Saturday, December 8, 2018

Il-13, Fas, and phagocytes

Neutrophils secrete fasL
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3278510/

Monocytes, eosinophils, and neutrophils express fas and this is a way to stop quickly inflammation

il-13 suppresses apoptosis
http://www.jimmunol.org/content/jimmunol/161/6/2863.full.pdf

Monocytes, eosinophils, and neutrophils all have il-13 receptors which means they do not go through apoptosis if il-13 is around.

During cytosolic infections by bacteria or parasites the myeloid Dendritic cells instead of intereacting with TH1 hands the MHC2 with a protein in it off to a basophil who then as the liaison shows the TH2 cells instead. TH2 cells then make il-13 not just il-4.

This means that when a cytosolic infection occurs and the CTL-fas ligand pathway is triggered the phagocytes are not going to apoptosis only the parasite infected cells. At least until the il-13 wears off.


Like viruses of the cytosol there is more than one way to kill bacterial infections of the cytosol.

cytosolic receptor for bacteria
https://www.nature.com/articles/s41586-018-0433-3


Monday, December 3, 2018

Do TH17 cells pop the infected organelles?

Hypothesis: TH17 are cells secrete il-20 cytokines which pop the organelles because they appear with infections that are further inside like vacuoles or the mitochondria.  A second popping is needed for the immune system to see the infection.  The question is how?

il-17a does call neutrophils which helps fight fungal infections

virus activates il-1beta
https://www.ncbi.nlm.nih.gov/pubmed/10358182

il-1beta and il-23 activate the differentiation of TH17
https://www.cell.com/cell-reports/pdf/S2211-1247(18)30225-0.pdf

il-23 is triggered by intracellular bacteria
http://www.jimmunol.org/content/183/12/8026

Hypothesis
The cytokines of  TH17 cells pop the organelles of the cell.

Reposted from before:

The il-20 Family is secreted by Th17

il-20 Family includes: il-26, il-19, il-22, and il-24

il-26 nucleus

il-19 disruption of mitochondria

il-22 chlamydia/ gonorrhoeae/ h.pylori in vacuoles

il-24 salmonella in the golgi

Nucleus: il-26

il-26 PORE  with DNA (used for a second popping of membranes like the mitochondria and nucleus or internalized infections)
https://www.nature.com/articles/ni.3211

( TLR-9 I had linked to being the net of the mitochondria )
http://angelabiggs.blogspot.com/2017/01/tlrs-toll-like-receptors-summary.html

il-26 and herpes viruses
http://journals.plos.org/plosone/article?id=10.1371/journal.pone.0070281

Mitochondria il-19

il-19 and acute kidney failure due to mitochondrial induced apoptosis
https://books.google.com/books?id=n9ocHWITPnoC&pg=PA51&lpg=PA51&dq=il-19+mitochondria&source=bl&ots=1sfmQISyik&sig=bgu8tG8Vy7EB0Q5SueB8jaFX8fE&hl=en&sa=X&ved=2ahUKEwi1nJrxk6PfAhVF4IMKHddSD_0Q6AEwBnoECAgQAQ#v=onepage&q=il-19%20mitochondria&f=false

th17 and herpes zoster
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5597651/



Golgi: il-24

salmonella nests inside of cells in vacole near golgi
https://www.ncbi.nlm.nih.gov/pubmed/18778407

il-24 protects against salmonella infection
https://www.ncbi.nlm.nih.gov/pubmed/1983073

Golgi and il-24 with melanoma (supporting connection)
https://www.ncbi.nlm.nih.gov/pubmed/15126330

golgi and ER relationship....IFNgamma
https://www.ncbi.nlm.nih.gov/pubmed/10712678

ifn gamma and tnf with salmonella
https://www.karger.com/Article/Pdf/163643


Vacuoles: il-22

Chlamydia moves inside of cells to replicate
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4886739/

chlamydia and il-22
http://europepmc.org/abstract/MED/24531835

il-23 triggers Th17 to release il-22 and il-17
https://www.ncbi.nlm.nih.gov/pubmed/24238108

H.pylori and il-23
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3342083/

H.pylori and il-22
https://www.ncbi.nlm.nih.gov/pubmed/26867135

H.pylori replicates in vacuoles
http://iai.asm.org/content/78/10/4157.full



Friday, November 30, 2018

TSLP and TFH

TSLP thymic stromal lymphopoietin is released by fibroblasts and epithelial cells

TSLP and TFH differentiation
http://jem.rupress.org/content/jem/early/2017/04/19/jem.20150402.full.pdf

TSLP and TH2 cells
https://onlinelibrary.wiley.com/doi/pdf/10.1002/eji.201041195

Does TH2 exposed to TSLP become TFH ?

TSLP activates Langerhans dendritic cells
https://www.ncbi.nlm.nih.gov/pubmed/17320941






Thursday, November 29, 2018

Basophils are the liaisons for the TH2 cells. (still working on this)

Basophils are the liaisons for the TH2 cells.

Visible infections

Basophils produce the burst of il-4 that develops TH2
https://www.ncbi.nlm.nih.gov/pubmed/14764715
http://jem.rupress.org/content/200/4/507

Basophils are antigen presenting cells to the Th2 cells using the MHC2 containing proteins of parasites or bacteria found in the cytosol.  Basophils can take MHC2 from mdendritic cells through trogocytosis.  Trogocytosis is the transfer of plasma membrane.
https://www.ncbi.nlm.nih.gov/pubmed/28096423

Basophils are required for the Th2 immunity to Haptens
https://www.semanticscholar.org/paper/Basophils-are-required-for-the-induction-of-Th2-to-Otsuka-Nakajima/0f9d25d27b6bbc6f3c5299f3b2db78d80a61a51e

Haptens are the incomplete antigens or peptides of toxins or poisons.

Urushiol of poison ivy is oxidated in skin cells and the hapten duinon is released

Penicillin can also be oxidized to be a hepatin.

The majority of allergic contact dermatitis involves hepatins and Basophils.

GM-csf Vacuole bacteria

When exposed to GM-csf the Basophil's secrete il-6 and help make th17
https://www.nature.com/articles/srep41744

GM-csf exposed mDendritic make il-23 which triggers TH17 cells

 GM-csf creates TH17 dependent on il-6
http://jem.rupress.org/content/205/10/2281

 TH17 triggers with both il-6 and il-23 and cause the popping of  vacuole bacteria (il-22)


il-3 Viral or cytosol parasites/bacteria like t.gondii or mycobacteria

il-3 increases the MHC2 on basophils and interactions between mDendritic cells occur.

 These cytosol bacteria infections will be presented to TH2 when such MHC2 are handed over from mdendritic cells to Basophils.

Non enveloped viruses use lysis to exit cells using low oxygen and viral proteins do dissolve membrane while histamine from basophils and mast cells increase the oxygen in the area


Tuesday, November 27, 2018

Autoimmune cross-targeting hypothesis of Rheumatoid Arthritis : Mycoplasmas and epstein barr virus or Mycobacteria and hepatitis C/ coxsackie

Autoimmune cross-targeting hypothesis: when two infections are on one target typically the immune attack on the larger infection is stopped. This "stopping" action can trigger autoimmune disease.

Autoimmune antibody in Rheumatoid Arthritis is  anti-ccp or cyclic citrullinated peptide

HLA-C allele confers risk for RA and cyclic citrullinated peptide antibodies
https://www.ncbi.nlm.nih.gov/m/pubmed/23901134/

HLA-C is the T cell mailbox for ER proteins

mycoplasmas infect the ER
https://www.ncbi.nlm.nih.gov/pubmed/4844719

Natural killer cells are responsible for ER and golgi infections (HLA-C and HLA-E). When infections occur in these areas no proteins make it to the surface of cells and they often appear naked.

It is possible that anti-CCP are to stop Natural killer cells from binding the HLA-Cs.

Like the case with aquaporin and ER viral infections the ER mycoplasma infection is halted but this time through HLA-C.

Mycoplasmas and RA
http://www.ncbi.nlm.nih.gov/pubmed/24097830
http://www.ncbi.nlm.nih.gov/pubmed/10618069 (infection found in synovial fluid)
http://www.ncbi.nlm.nih.gov/pubmed/17122006

Not a new idea 1971...mycoplasmas and RA
http://www.ncbi.nlm.nih.gov/pubmed/5165178

Synovial membrane antibodies and RA
http://www.ncbi.nlm.nih.gov/pubmed/16184347

Virus: epstein barr and RA (nuclear virus)
https://www.ncbi.nlm.nih.gov/pubmed/28499895
http://www.ncbi.nlm.nih.gov/pubmed/25407647

The Rheumatoid arthritis group that has negative anti-CCP has conferred risk with HLA-DR3 : a cytosolic mailbox.
https://www.ncbi.nlm.nih.gov/pubmed/16200610

Type 1 diabetes is closely tied to HLA-DR4 and HLADR3

HLA-DR3 and coxsackie
https://www.ncbi.nlm.nih.gov/pubmed/12941542
https://www.ncbi.nlm.nih.gov/pubmed/9498628
https://www.ncbi.nlm.nih.gov/pubmed/12845430

HLA-DR3 and Hepatitis C
https://www.ncbi.nlm.nih.gov/pubmed/9490691

These viruses infect the Golgi

HLA-G (the golgi mailbox) has also been linked to RA
https://www.ncbi.nlm.nih.gov/pubmed/16916651?dopt=AbstractPlus

hepatitis C and the golgi
http://www.pnas.org/content/114/17/E3462

coxsackie and the golgi
https://jvi.asm.org/content/81/13/6785

This form of rheumatoid arthritis could be connected to gangliosides
https://www.ncbi.nlm.nih.gov/pubmed/8761183

since viral infections ten to create "naked cells" and this is the only way NK can bind

This form of RA can develop neuropathy
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4026612/

In this case the large infection could be mycobacterias
http://www.rheumatologynetwork.com/arthritis/latent-tuberculosis-infection-ra-disease-and-diagnosis

nodular vasculitis and mycobacteria
https://www.ncbi.nlm.nih.gov/pubmed/20666819

This mycobacteria form of RA would involve Basophils.  They would take the MHC2 from the TH1 and then the basophils would present to the TH2. Basophils are the liaisons to TH2 cells. They do this when there are parasites or mycobacterias hiding in the cytosol.














Friday, November 23, 2018

Aquaporins allow motility in immune system cells. When antibodies against these water-pores appears in autoimmune disease is it when the immune system is stopping a pathway?

Autoimmune cross-targeting hypothesis: when two infections are on one target typically the immune attack on the larger infection is stopped. This "stopping" action can trigger autoimmune disease.

For transverse myelitis two infections are suspected: the flu virus and fungal infections of the spinal cord like aspergillus ? Or is it mycobacteria?

For Neuromyelitis optica two infections suspected: mycobacteria and the a virus....flu, herpes, dengue...

Fungal infections primarily involve the recruitment of neutrophils.

Transverse myelitis and aquaporin :  some have aquaporin-4 but not all. Are there 2 types?
https://jamanetwork.com/journals/jamaneurology/fullarticle/1733321

Neuromyelitis optica and anti-aquaporin-4
https://www.ncbi.nlm.nih.gov/pubmed/18808744
https://hub.hku.hk/bitstream/10722/250540/1/content.pdf

Antibodies to aquaporin 8 and 9 in SS Sjögren's syndrome 
https://academic.oup.com/rheumatology/article-abstract/56/12/2114/4100683

transverse myelitis and ss Sjögren's syndrome (fungal)
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3502814/

neuromyelitis and tuberculous (mycobacteria)
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3938476/

Eosinophils combat mycobacterias. Is this why Neuromyelitis has anti-aquaporin 4?
Aquaporins are used for motility by the immune system cells. (ha ha makes you think of them as little motor boats)

Eosinophils and aquaporin-4
https://www.sciencedirect.com/science/article/pii/S096758681731069X

macrophages M1 use aquaporin-1 for motility
https://www.ncbi.nlm.nih.gov/pubmed/25719758

macrophage M2 and aquaporin-3
https://www.nature.com/articles/srep25781

dendritic cells express aquaporin-3 and aquaporin-5
https://onlinelibrary.wiley.com/doi/pdf/10.1002/ajh.10476

Aquaporin-9 has high expression in  Neutrophils for motility
https://www.nature.com/articles/srep15319

Neutrophils combat fungal infections.  Is this why Sjogren's syndrome has anti-aquaporin 9 appears?

Aquaporin 8 localized to mitochondria
https://www.sciencedirect.com/science/article/pii/S2405580815000898

Is the immune system trying to stop the larger infection by targeting the aquaporins used for motility by the immune system? Are these IgG4 or IgG1? I would think it would be IgG4 if it was the immune system was shutting itself down.

The problem arises because aquaporin-4 is the main water channel in nerves
https://www.ncbi.nlm.nih.gov/pubmed/15561407

Aquaporin- 9 has high expression in glial cells (non neural cells of the brain and spinal cord)
https://www.ncbi.nlm.nih.gov/pubmed/15450351
https://www.ncbi.nlm.nih.gov/pubmed/15561412

Is the phantom pain from the glial cells in Sjogren's?

Does not seem to match up yet:

IgG4 related disease
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4902347/

Classified autoimmune IgG4
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5816565/

previous post:

flu vaccine and transverse myelitis
https://www.ncbi.nlm.nih.gov/pubmed/20697056
https://www.ncbi.nlm.nih.gov/pubmed/21598817

lupus and transverse myelitis
https://www.ncbi.nlm.nih.gov/pubmed/2179553
https://www.ncbi.nlm.nih.gov/pubmed/3632736
https://www.ncbi.nlm.nih.gov/pubmed/1643455
https://www.ncbi.nlm.nih.gov/pubmed/9707792

transverse myelitis, MS,  neuromyelitis optica (mycobacteria?)
http://journals.plos.org/plosone/article?id=10.1371/journal.pone.0100672

flu virus and neuromyelitis optica
https://www.ncbi.nlm.nih.gov/pubmed/21804290

dengue virus and neuromelitis optica
https://www.ncbi.nlm.nih.gov/pubmed/29475624

herpes zoster and neuromelitis optica
http://n.neurology.org/content/86/16_Supplement/P6.159

Idiopathic transverse myelitis and HLA-DR2
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3151596/

HLA-DR2 and the flu

oral polio vaccine and neuromyelitis? or is this AFM?
https://www.ncbi.nlm.nih.gov/pubmed/16630313
https://www.ncbi.nlm.nih.gov/pubmed/19269246
https://www.ncbi.nlm.nih.gov/pubmed/9842449

would this be more of an AFM because it's an enterovirus?

oral polio vaccine paralysis issues factsheet
http://www.who.int/immunization/diseases/poliomyelitis/endgame_objective2/oral_polio_vaccine/VAPPandcVDPVFactSheet-Feb2015.pdf

Fungal infection and transverse myelitis
http://insights.sagepub.com/fungal-partial-transverse-myelitis-of-the-cervical-spine-in-an-immunoc-article-a4645
http://www.exoticpetmedicine.com/article/S1557-5063(15)00013-0/abstract

schistosomiasis and transverse myelitis
https://www.cdc.gov/mmwr/preview/mmwrhtml/00000385.htm
(schistosomiasis are parasitic snail worms)


Saturday, November 10, 2018

The Immune system summary : work in progress: Omentum B1 cells added.

The Innate Immune system

The Innate immune system is the inherited immune system that is based upon recognizing the core unchanging features of infections.

Your skin's epithelial and fibroblast cells are the first line of defense agains foreign infections.

After the skin barrier protection is broken the sentinel macrophage greets the visitor. Macrophages do not travel to the lymph but kill the foreign infections engulfing them like a pac-man  and alert the rest of the immune system. The LPS of a bacteria stimulates the macrophage to become active and produce il-6 which signals the creation of the innate immune system army.

il-6 stimulates the production of Neutrophils, Mast cells, Basophils, Eosinophils, and more monocytes. Monocytes can develop into macrophages or dendritic cells.

Here is a quick summary of the innate's immune system army:

Macrophages which are the immune system's sentinels. Macrophages kill and alert of foreign infections of any kind.

Neutrophils are specialized to destroy and consume bacteria. Neutrophils throw down nets to trap infections in an area.

Mast cells help to identify if it is a viral or bacterial infection then release histamine to bring more immune system cells to the area, the next adaptive immune system. Skin derived mast cells taste through endocytosis the infected area for viruses. While TLR butterfly nets on the surface of bone derived mast cells look for bacteria.

 Eosinophils help to breakdown extremely large infections into smaller bite size pieces for neutrophils.

Basophils Like mast cells there are 2 types.  Basophils aid in attacking  infections like mycobacterias by releasing heparin and serotonin while a second type aids in the viral attack. The duty of Basophils are to help mast cells transition the immune system from innate to adaptive but Basophils have a special relationship as a liaison to TH2.  ( Basophils appear to create the il-4 burst which develops the TH2 cells from TH0 and they can antigen present to TH2 cells which will be covered in the Adaptive Immune system)

How does the Innate immune system start?

For invading bacteria our immune system has evolved an attack based on the standard surfaces of the bacteria.  There are three basic bacterial surfaces: flat and reachable, mannose sugar covered and semi-reachable and completely covered unreachable surfaces. The flat surface of something like staph can be dealt with through an antibody binding pathways called Complement.  The long mannose sugar strand covered type of bacteria's like strep are dealt with using a Mannose Lectin pathway.  The bacterias like e.coli that have so much surface junk that nothing can be built on the surface are dealt with using an Alternative pathway.  In attacking the surface of the bacteria there are two goals.  To place gripper receptors for phagocytosis by macrophages or neutrophils on the bacteria or to create a "membrane attack complex" which forms a pore into the bacteria which leaks the guts of the bacteria out thus killing it. 



The Complement Pathway
Macrophages which are the sentinels of the immune system have TLR sensors.  These TLR sensors are butterfly net  type of attachments that when triggered stimulate the macrophage to produce il-6.  il-6 cytokines are messages sent to tell B cells to make the generic simple IgM antibodies.  This IgM pentagon antibody with it's 5 legs easily bind foreign objects in a non specific way. The FC portion of the antibody interacts with complement proteins to slowly create the phagocytosis handles and the MAC pore.

The Mannose-Lectin Pathway 
This pathway involves sticking to long sucrose hairs and then slowly dropping the phagocytosis handles and MAC pore pieces down onto the surface and the bacteria is killed.

The alternative pathway
Because nothing can be built upon the surface the MAC pore is assembled off the surface and then plunged in as one giant unit. (no phagocytosis handles can really been seen on this surface)


The Adaptive Immune system

This is the stage where the immune system adapts to an infection and creates antibodies which bind specifically.  This is not inherited this is created based on current environment exposure.  First they must not recognize self antigens. B cells are educated in the bone marrow to not recognize outer self antigens.  T cells are educated in the thymus to not recognize self antigens inside host cells.  The receptors produced from these educations should only bind foreign matter.

There are four major immune system areas: the lymph glands, the spleen, the peyer patches, and the omentum milky spots.  Lymph glands are responsible for lymph fluid, peripheral tissue, and surface infections.  The spleen monitors the blood. The peyer patches monitor the mucosal membranes of the intestine through M cells. The Omentum's milky spots are lymph like glands that monitor the abdomen specifically the transition of nutrients from the intestine to the blood stream.

B1 cells of the omentum are the primary source of IgM and are the primary producer of the monomer form of IgA in response to il-5.

Langerhans carry antigens to the lymph glands' follicular dendritic dells.

Marginal Zone B cells are the spleen's version of langerhans.

Myeloid and plasmocytioid dendritic dells have evolved like macrophages from myeloid (bone marrow) cells but they do not appear with the innate system and like Langerhan cells they are antigen presenting cells for foreign antigens found inside of cells.

B cells are the antibody producing cells of the immune system.  Their B cell receptors are educated in the bone marrow to know outer self antigens and react only to foreign outer antigens.

T Cells are the coordinator of what type of antibody to make.  Different T cells are assigned to different zones.  They look at the antigen presenting cells then secrete the correct cytokine to the B cells.  The T cells are educated to know the self antigens of the inside and the T cell receptor when only react when binding an unknown antigen from inside the infected cell.

The follicular dendritic cell, which are starfish-like shaped cells,  present antigens to a B cell.  B cells use a membrane bound antibody called  a BCR ( b cell receptor ) to bind the antigen.  This B cell undergoes somatic hypermutation of the BCR until the binding is strong enough to remove the antigen from the dendritic cell and pull it into the B cell. The B cell then processes the antigen and acts as an antigen presented to T follicular cells.  The T follicular cells then stimulate the B cells to make antibodies.  Note that these B cells that were already active making IgM and must go through somatic switching to  the IgA, IgE or IgG1.

When it is a viral infection macrophages or skin derived mast cells find they call myeloid and plasmacytoid dendritic cells to the area. Dendritic cells taste the area then  travel to lymph glands where they act as antigen presenting cells to T cells.  When the TCR (T cell receptor) of the T cell identifies a non self DNA or RNA segment it then interacts with a B cell stimulating it to produce antibodies. In summary, there are three distinct antigen zones that the immune system focuses on: the outer antigens, the cytosol antigens, and the nuclear/mitochondrial antigens.


All of these are T follicular cells but the Tfh comes from Th2.

the Tc follicular
virus: HIV have TFH cells with: pd-1 icos cd40 and cxcr5 : il-10
http://www.jimmunol.org/content/jimmunol/early/2016/07/30/jimmunol.1600143.full.pdf?with-ds=yes

the TH1 follicular
influenza TFH: pd-1, icos cxcr3. cxcr5 : ifn gamma and  il-2
https://www.ncbi.nlm.nih.gov/pubmed/27231124
https://www.ncbi.nlm.nih.gov/pubmed/23486778

The starfish shape is the FDC cell showing the B cell the antigen.


The CD4 and CD8 act as clips holding the MHC mailboxes for the T cell to look in with their TCR. CD4 clips are on Tfollicular helper cells and Thelper cells while CD8 are on the TC cells.  The MHC1 mailboxes which includes HLA-A of the nucleus and HLA-B of the mitochondria hold up viral nucleotide antigens.  The MHC2 which includes HLA-dr and HLA-dq hold up antigens of the cytosol.

Note that Chlamydia as a bacteria gives rise to IgG3.  Why would a bacteria give rise to IgG3? Chlamydia is named for the greek word Khlymus which means cloak. Chlamydia wraps around the nucleus of the cell it infects.

 While IgG3 is known to bind viruses that infect the nucleus or mitochondria. (HIV vaccine that was 30% protection was due to increased IgG3 antibodies)

The TH17 linked bacteria and parasites may be linked to IgG3 antibodies. (under consideration right now)

The outer antigen B cell is the one that goes through somatic hypermutation improving the binding of the antibody.  The isotype of the antibody made the B cell changes based on the hormone of the area.  The spleen which grows into the pancreas would see high levels of insulin. The intestine which is in a constant state of replacement exposes the peyer patches to high levels of growth hormone. While your skin and the lymphs close to them would see high levels of insulin like growth factor which is involved with the development of new skin cells. The hormones of each of these areas dictates the isotype of the antibody.  The B cells will make IgE at the lymph glands,  IgA at the peyer patches, and IgG1 at the spleen.  The exception to this is when a parasite triggers il-5 which triggers the monomer form of IgA. Normally only the dimer form of IgA is produced  which in the intestine aids in the clumping and disposal of infections where the clumps are washed away.   Parasites like worms tend to be larger and can not be clumped and washed away rather they need to be broken down.

The B cells of of the outer region first make IgM after il-6 exposure then class-switch to IgE or IgG1 or IgA. The B cells of the inner regions, the cytosol or mitochondrial/nuclear regions, do not make IgM first but are triggered by il-3 exposure.

In addition to the start cytokines il-3 or il-6 the B cells need to be activated by ICOS an inducible co-stimulatory molecule, il-21, and a cytokine that informs it of the region IgG region.  T cells only express icos after cd28/pd-1 and TCR stimulation.

The above diagram is missing the T cell activation B7 receptors.  For simplicity I have removed the CD4 and CD8 clips and focused on them.

The B7-h1 inhibits while the others stimulate...perhaps because you don't want CTLs to be fast to choose to kill. As pd-1 expression goes down with TCR stimulation on the Tc activation increases?


IgG3 increase x3 in pd-1 negative mice

https://www.ncbi.nlm.nih.gov/pubmed/9796923






For large visible infections il-6 stimulates B cells but for viral infections it is the skin derived mast cells that turn the B cells on with il-3.



MHCs are the mailboxes that hold up antigens for T cells aka HLAs.  If you look at viral infections the the mailboxes that are associated with them you see this pattern. HLA-D covers infections in the cytosol and infections outside of the cell probably because so many infections when given a chance move inward hiding in the host.


So the butterlfy-net TLRs carried by macrophages and dendritic cells when triggered release different IFNs which then triggers the expression of the correct HLA mailbox.  The matter that had been taken up by endocytosis, which tagged the TLRs is then processed in dendritic cells and held in the correct HLA mailbox.  Myeloid Dendritic cells work with cytosolic antigens.  Plasmacytoid dendritic cells work with the nuclear or mitochondrial antigens.


Note that IFNgamma is special in that it is a cytokine for all infections not in the nucleus or mitochondria and is used by the TH1 cells to mean an infection in the Cytosol region.  This may have evolved because if the ER is compromised than nothing reaches  the surface of the infected cell and they are easy to identify as problematic. 


When a host cell has viral infections of the ER no proteins reach the surface of the cell and the host cell  becomes naked.  When NK's KIR binds to HLAs it knows the cell is healthy and won't attack.  When a cell has no HLAs to bind the KIR the NKis triggered to attack.




il-3 sends the nk on the viral pathway while il-6 sends the NK on the bacteria pathway for something hiding in the cytosol of cells.


Specialty cells:

TH9 cells are for Cancer cells.  When a tumor triggers il-4 but no il-5 varifies the presence of a bacteria and TGF-b1 notifies of a nuclear virus then TH9 cells are created.  il-9 is a cytokine that has been found to suppress tumor growth and then il-21 helps to trigger Th17 cells.

TH17 cells are for second poppings.  If a bacteria has moved inside of a vacuole or inside of the golgi then it needs to be popped out. The same is true for viral infections of the nucleus and mitochondria.





maybe? TGF type helps?



Note that the TH17 cell hypothesis still needs to be proven,

Another hypothesis that needs proving is how the cytosol viruses are seen by the IgG2 antibodies using 25HC.




The CTLs function differently in the inner regions.  Il-2 stimulates Fas ligand killing.  Fas expression in cytosol infected cells.  il-21 increases killing through Tcr stimulation.



Note that there are 3 ways for cells to die. Necrosis which is premature death due to injury, pyroptosis which is programmed death due to an infection and then apoptosis which is a programmed cell death through the mitochondria which the cell can choose to do in old age. 

Granzyme A and inflammazones create il-1b which trigger pyroptosis.  Granzyme B triggers apoptosis.


The Gamma delta T cells and the NKT cells work together to produce antibodies against lipids. (hypothesis) Note here is where somatic hypermutation would occur for the viral lipid antigens. The invariant form would involve the myeloid dendritic cell's cytosol lipid antigens and the outer visible lipid antigens picked up B cells.




Natural T regulatory cells are used to focus the immune system and then inducible T regulatory cells stop the process at the end. I say CTL but it should be the Tc pathway.





The B7 receptors patterns could also tell the cells when to become T regulatory cells (hypothesis)




Chemokines are involved with the migration of immune system cells. The three antigen zones become apparent when organizing the chemokine receptors.


Chemokine receptors also link the immune system cells to the correct immune system gland.



What happens when bacteria or parasites are hiding in the cytosol ?

The Basophils create the TH2 that secrete il-13.
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5293035/

Basophils are the bridge back to the outer antigens pathway. Trogocytosis involves the  transfer of plasma membrane between antigen presenting cells and other immune system cells so that they may express the surface molecules specifically antigens in MHC2 on their own surface. In this case the myeloid dendritic cell is expressing an antigen that is a forein protein in the MHC2.  By transferring this to the Basophil the correct immune system pathways will be triggered. The newly formed TH2 secreting  il-13 informs the eosinophils that the infection is in the cytosol of infected cells.

il-13 functions similar to il-4 however il-13 suppresses apoptosis. Infections are held by the myeloid dendritic cells' MHC2 and trigger the il-2 CTL which use Fas to trigger apoptosis in infected cells.

Eosinophils, monocytes, and neutrophils all have fas which allows for the halting of inflammation of this pathway quickly but if they have seen il-13 which they also have a receptor for they will not go through apoptosis.  This means that when a bacteria or parasite has moved into the cytosol the CTL with its Fas ligand will kill only the infected cells.  When the neutrophils, eosinophils, or monocytes see the parasite released from the cytosol of the apoptosis infected cell the parasite can be exterminated.  Only when the il-13 exposure wears off can the phagocytes again be triggered by fas themselves.

How are cytosolic viruses seen and killed? CTL fas ligand cells kill the infected cells through fas or 25hc which is released by activated macrophages.  25HC is only grabbing cytosolic viruses because it can't see the viruses in the nucleus or the mitochondria.  The cytosolic viruses are held outside of the infected cell and the IgG2 antibodies are able to interact with them there and set off an innane system pore to kill infected cells.

 While cytosolic viruses burst through the plasma membrane the  nuclear and mitochondrial viruses use membrane budding,  25HC blocks nuclear and mitochondrial viruses by changing the plasma membranes. Only when theses inner viruses go through the golgi does 25HC then try to stop them by changing the cholesterol fluidity of the plasma membrane so the enveloped viruses can't bud.

What about exosomes? They deliver what is in cells, specifically infected or stressed cells, to dendritic cells


Exosomes may also be involved in Tolerance.

Tolerance is the "self education" given the B and T cells. B cells have been taught the external antigens in the bone marrow while T cells have learned the internal DNA/RNA antigens in the thymus. These self educations where all genes are expressed are called Central Tolerance.

Peripheral Tolerance is given to B and T cells by the gatekeeper cells of the lymph glands: the Lymphatic Endothelial cells.  Lymphatic endothelial cells express the tissue specific genes of the cells of their area. They also sample and wear the antigens commonly found in their area.


These lymphatic endothelial cells will only allow in T and B cells that do not react with the self antigens specific to the tissues of the of the peripheral area into the lymph gland.  (B cells are hypothesized to be educated too but this is not proven)

Current ideology is that if we can get antigens from a transplanted organ into the LEC tolerance to the transplanted organ will occur. The question is how is this done exactly and how often do LEC update their antigens.

Over simplified FC receptors and antibody relationship

Fc gamma : IgG

Fc epsilon: IgE (phagocytosis or degranulation)

Fc alpha: IgM , IgA eosinophil degranulation or IgA neutrophil nets


The dimer of IgA has no FC exposed to bind and has the ability to cross the mucosal membrane.

The hormone connection of antibodies can also be seen with the GSMD pores. Why ? Does the core of the pore match up with the pore of the middle of the antibody?

IgE at the skin's IGF-1  with the GSDMA pore?
IgA GH with GSDMB ?
IgG1,  insulin with GSDMC ?

The GSDM is made by the caspase-1 of inflammasomes.  There are 2 major types of inflammasomes.
Both can end in either apoptosis or pyroptosis based on the type of infection that started them.




When cytosol infections trigger apoptosis there is the option of pyroptosis.  Viral infections favor apoptosis while parasitic cytosol infections favor pyroptosis. As suggested above the GSDM pore created may function as a window for esosinophils to see the parasite inside.

Apoptosis can occur from DNA damage triggering p53 or from the triggering of FAS which turns oh the Death inducing domain leading to caspase. (DISC) In these cases no pyroptosis can occur.


Apoptosis:




Tuesday, October 30, 2018

How does il-3 work? corrected

This blog post may change.  It looks as if il-3 behaves like il-6 in converting B cells into plasma cells.

il-3 and il-6
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2189411/

https://www.researchgate.net/publication/20372389_Human_recombinant_IL-3_stimulates_B_cell_differentiation

 il-3 produced by skin matured mast cells when they see viruses would stimulate the B cells to become plasma cells after they interact with TH1 or TC producing IgG2 or IgG3.

il-6 stimulates B cells to start producing IgM when a visible infection was seen.  The B cells then interact with Follicular dendritic cells or langerhans to produce IgA IgE or IgG1.



 The cytosol antigens involve the TH1-B cells and would have IFN gamma producing IgG2 instead of il-4. The mito/nuclear antigens would involve Tc-B cells and il-10 producing IgG3.

il-5 validates that it is not a tumor growing due to a viral infection causing cancer?

Note that gm-csf is also released by TH17 after the vacuole or inner organelle is popped.

outer antibodies and B cells: insulin IgG1 spleen,  GH IgA peyer patches , IGF-1 IgE lymph






Two types of human mast cells
http://www.pnas.org/content/83/12/4464?ijkey=0c1e165e66f17fb90b06151a9409ad54cba6eae9&keytype2=tf_ipsecsha

Skin derived and Bone derived mast cells
https://www.ncbi.nlm.nih.gov/pubmed/15214039
https://www.ncbi.nlm.nih.gov/pubmed/15210814


TLR 3 Golgi
TLR7 Nucleus
TLR9  mitochondria

Eosinophils to divide into 3 groups if you look at chemokine receptors

the cytosol antigens TH1 pathways
cxcr3 and eosinophils
https://www.ncbi.nlm.nih.gov/pubmed/10903763

the nuclear/mitochondria antigens Tc pathways
cxcr4 and eosinophils
https://www.ncbi.nlm.nih.gov/pubmed/10820276

the outer antigens TH2 pathways
ccr3 and eosinophils
https://www.ncbi.nlm.nih.gov/pubmed/12496441

il-3 and IgE receptors on Mast cells (binding of IgE decreases il-3)
https://onlinelibrary.wiley.com/doi/pdf/10.1002/1521-4141%28200208%2932%3A8%3C2308%3A%3AAID-IMMU2308%3E3.0.CO%3B2-X

il-3 decreases IgE antibodies
https://www.ncbi.nlm.nih.gov/pubmed/458056
https://www.ncbi.nlm.nih.gov/pubmed/80144

IL-3 were found to release more histamine and LTC4 but not PGD2
PGD2 is involved with microbial infections

Leukotrienes type LTC4 elevated in viral infections
https://www.ncbi.nlm.nih.gov/pubmed/14533659

Staph infections appear to evade detection and destruction by confusing the immune system. The trigger of leukotrienes makes it look like a viral infection is occurring.

Staphylcoccous aureus' enterotoxins induce leukotrienes
https://www.ncbi.nlm.nih.gov/pubmed/11531797

LTB4 acts against mycobacteria
http://journals.sagepub.com/doi/pdf/10.1177/000456329703400205

5-HETES becomes LTC4 or LTB4

gm-csf from il-23 stimulated TH17
https://www.nature.com/articles/ni.2044

Thursday, October 25, 2018

TSLP from epithelial and keratinocytes warn of bacteria

Epithelial and keratinocytes produce TSLP when infected.

TSLP stimulates langerhans cells and dendritic cells.
There are two isoforms of TSLP: a long and a short

The long form which appears with atopic dermatitis  (staph) simulates the myeloid dendritic cell to produce il-23 while the short form which appears with celiac disease (e.coli) stimulates Langerhans dendritic cells.

TSLP Thymic stromal lymphopoietin stimulates TH1 and Th17
https://ard.bmj.com/content/70/Suppl_2/A43.3

TSLP and il-13 Th2 cells
https://www.jacionline.org/article/S0091-6749(07)03504-X/fulltext

il-13 appears with bacterial infections that move inside of host cells.  Visible bacteria or parasites that stay outside of host cells trigger il-4 pathways

atopic dermatitis, TSLP, and il-13
https://www.jacionline.org/article/S0091-6749(07)03504-X/fulltext

staph triggers TLR2 producing TSLP
https://www.ncbi.nlm.nih.gov/pubmed/21050945

staph moves into skin cells and hide in vacuoles
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3417557/

TSLP activates myeloid dendritic cells which are responsible for triggering TH1 cytosol infection pathways
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3645262/

Th17 cells pop inner organelles

GM-csf is also involved with vacuole bacteria. GM-csf is secreted by macrophages, T cells, Nk cells, and mast cells.

GM-csf is stem cell stimulating: basophils, esoinophils, and neutrophils

GM-csf exposed Basophil's produce il-6 and trigger th17
https://www.nature.com/articles/srep41744

GM-csf exposed mDendritic make il-23
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4297527/




Thursday, October 18, 2018

Is autoimmune triggered paralysis caused by enteroviruses, Natural killer cells, and GM gangliosides?

Autoimmune cross-targeting hypothesis: two infections on one target tissue with one inside and one outside triggers autoimmunity.  Typically the outer larger infection is the one stopped and the attack on the internal viral infection is continued.

But what if when enteroviruses infect the ER involving the Natural Killer cells  the entroviruses are stopped first?

Here are my suspects (unproven)

Nodding disease: T. Brucei and polio live vaccine
Epilepsy: T gondii/t.cruzi/malaria and enterovirus
Absent seizure: mycoplasma polio or enterovirus
Guillain Barre: Campylobacter jejune and coxsackie
AFM/Hopkins: Staph and D68
peripheral neuropathy: e.coli and coxsackie

AFM and staph not just virus
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4536609/

Do autoimmune diseases involving enteroviruses involve the stopping of Natural killer cells? Instead stopping the attack on the large infection the immune system stops this pathway?

il-15 calls natural killer cells
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2191697/

Lower NK cells after seizures
https://www.ncbi.nlm.nih.gov/pubmed/18387608

https://www.sciencedirect.com/science/article/pii/S0014488608000356

https://www.researchgate.net/publication/20211933_Reduced_Natural_Killer_Cell_Activity_and_Okt4Okt8_Ratio_in_Epileptic_Patients

https://onlinelibrary.wiley.com/doi/abs/10.1002/hup.470080608

Lower NK in Guillain Barre
https://www.ncbi.nlm.nih.gov/pubmed/9619642

Peripheral neuropathy and low NK   aka "NK leukemia"
https://www.ncbi.nlm.nih.gov/pubmed/9710063
https://www.ncbi.nlm.nih.gov/pubmed/8414048
https://www.researchgate.net/publication/15601292_Natural_killer_cell_lymphoproliferative_disease_associated_with_neuropathy

How does the immune system stop NK cells?

Ganglioside antibodies are found in Guillain Barre and peripheral neuropathy so are they involved with stopping the NK cells?

guillain barre anti-ganglioside antibodies
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3422685/

peripheral neuropathy and anti-gangliosides
https://jnnp.bmj.com/content/75/12/1765

Gangliosides inhibit NK cells
https://www.ncbi.nlm.nih.gov/pubmed/2598999

ganglioside GM2 as a target for NK cells
https://onlinelibrary.wiley.com/doi/pdf/10.1002/jcla.1860010211

https://www.semanticscholar.org/paper/Ganglioside-GM2-on-the-K562-cell-line-is-recognized-Ando-Hoon/1437bc6c70867f826ce64591ffe2370aaf65b008

GM3 and NK
http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.502.322&rep=rep1&type=pdf

Gangliosides are highly concentrated in the nervous system

diagram of glycolipids
http://www.brainkart.com/article/What-are-glycolipids-_27515/

diagram of Guillain Barre with anti-gangliosides
http://www.immunopaedia.org.za/wp-content/uploads/2014/12/axonal-or-End-Plate-Terminal-Damage.jpg

so the reason for the formation of anti-ganglioside antibodies according to the Cross-targeting hypothesis is that the immune system can only deal with one infection at a time.  Enteroviruses which  infect the ER and trigger NK cells are shut down so that the immune system can focus on the bacterial infection. The problem is that the anti-ganglioside does more than block NK from seeing GM2. Thus the paralysis.

AFM (acute flaccid myelitis) and anti-ganglioside
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5976313/
https://www.ncbi.nlm.nih.gov/pubmed/29028962

Monday, October 8, 2018

Combining the T gammadelta hypothesis with the autoimmune cross-targeting hypothesis.

The T gamma delta hypothesis was that Tgd function like B cells to produce gamma delta antibodies against lipid antigens which get confused with the IgG1 of B cells.    What is important is the idea that these are completely different immune system "couples". Instead of T and B it is NKT and T gamma delta.

Surmised cytokines



In order to create IgG4 the B cell must switch T cell partners and see a different cytokine. There is confusion and mixing. Tfh making il-4 for the outer antigens of E.coli while at the same time Tc would be making il-10? 


Possible? 

Can we show that these are Gamma delta antibodies and not IgG1?


Just for fun : IgG gamma delta mycobacteria (cytosol lipid infection)
                      IgG gamma delta Bacteria ( visible lipid  infection )
                      IgG gamma delta virus (lipid coat)
I just made this up....right now they are all lumped together as IgG1

3 different gamma delta elements in the T gamma delta receptor
https://www.ncbi.nlm.nih.gov/pubmed/7511639
                   

Gram positive Bacteria lipid A held by cd1.c  and cd1.b (monocytes and macrophages)
https://www.ncbi.nlm.nih.gov/pubmed/19948070

cd1.b on macrophages (cdl.b induced by il-4)
https://www.ncbi.nlm.nih.gov/pubmed/9175583

So cdl.c and cdl.b  both end up producing the IgG gamma delta B ?

HIV and cd1.a and langerhans
https://www.ncbi.nlm.nih.gov/pubmed/17442711

Friday, October 5, 2018

Correction on Cytokines and B cells becoming plasma cells and producing antibodies


I had il-4 as always with il-21 inducing B Cells but that didn't make sense because the B cell needed to know who it's T cell parter in order to make the correct antibody. Further the production of  IgG4 with a partner switch supports the Autoimmune Cross-targeting Hypothesis.



Possible? Are the cytokines matched up correctly?

Note that insulin creates IgG1, growth hormone creates IgA dimer, and IGF-1 creates IgE. 

Does that mean that the IgG4 goes against the hormone in control first? anti-insulin, anti-GH, anti-IGF-1?  unless it is a vacuole bacteria or fungal? Then it is IgG4 to neutrophils ? "ANCA" ?

Autoimmune Cross-targeting: Two infections on one tissue triggering the immune system. One inside while one is outside the tissue's cells 

Wednesday, October 3, 2018

Two types of CTL: CTL-Fas with cytosol viral infections and CTL-TCR with nuclear or mitochondrial infections.

Hypothesis: A cytosolic virus triggers the TH pathway with il-2 primed CTL which uses Fas to destroy cells.  This can be seen in Type one diabetes where the cytosolic flu virus can trigger the disease,  The nuclear virus HBV triggers the the Tc pathway where il-21 primes the CTL to kill using it's TCR which looks into the MHC1 of cells. This Tc pathway also involves TH17 cells to pop the nuclear membrane with il-26 and then il-17F to call CTL.

Type 1 diabetes, CTL and fas
https://www.ncbi.nlm.nih.gov/pubmed/15466911
http://diabetes.diabetesjournals.org/content/51/5/1391

Flu virus, fas CTL
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC1143766/

CTL and fas
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3088981/

Fas binding induces apoptosis

Granzyme A and apoptosis CTL induced death
http://jcb.rupress.org/content/167/3/457

CTL killer with granzyme B
https://retrovirology.biomedcentral.com/articles/10.1186/1742-4690-9-S2-P13

Platelets mediate CTL in HBV liver damage
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2908083/1

platelets contain TGF-b1
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3271718/

TLR9 and HBV
https://www.ncbi.nlm.nih.gov/pubmed/24942353

TLR9 /TGF-b1 pathways and blood
https://www.ncbi.nlm.nih.gov/pubmed/28356164

Th17 and HBV induced liver damage
https://www.ncbi.nlm.nih.gov/m/pubmed/28731149/

TBF-b1and Th producing il-21
https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0064612

il-21 and CTL TCR
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3042849/

il-21 and granzyme B
https://www.sciencedirect.com/science/article/pii/S0022202X17313106

il-2 increases all 3 granzyme A,B, and C
http://www.jimmunol.org/content/175/12/8003






unless il-5 triggers the monomer version of IgA the hormones appear to dictate

Tuesday, September 4, 2018

Eosinophils hypothesis



Appears that there are 5 types of eosinophils

Complement Eosinophils : C1q,  C3b/C4b, iC3b receptors : Bacteria : granulation

GM-CSF Eosinophils : Low affinity cd32 FcgammaR2 (IgG receptor) : vacuole Bacteria : granulation

il-5 Eosinophils :  cd89 Fc alpha R1(IgA receptor) : Parasites: granulation

il-3 Eosinophils : Fc epsilon R1 (IgE receptor) high affinity:
                              Fc epsilon low affinity receptor

 Viral Eosinophils that contain RNases

il-4 seems involved with antigens outside of the house cell while il-13 seems involved with antigens of the cytosol (visible parasite vs. one that moves into the cytosol of the host cell.



Do the Macrophages clean up the IgE antibodies?
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC1421858/


Do Platelets? They appear to have storage pools if IgE
https://www.sciencedirect.com/science/article/pii/S0091674997702306

Hypothesis: Platelets clean up IgE


Thursday, August 30, 2018

32 medical hypotheses (the 25HC hypotheses #25 is being reconsidered)

1. Allergy hypothesis: Allergies reveal the infections we have.  Severe allergies and infections can be matched up: peanut and Staph, bee and T.gondii, daisy and Clostridium, poison ivy and spirochetes. If an infection can be killed by a compound or inhibited by the compound our immune system sees the interaction and we associate all the compounds present with the infection.  If an infection makes a pigment from a compound we will react to that too.  For example aflatoxin with peanuts could cause staph to counter respond.  Our immune system would identify everything there at the scene of the crime as part of the infection.

2. Quorum hypothesis: Infections talk using quorums and these quorums interfere with our body's pathways. ( for example mycobacteria's cGMP causes such things as type 2  diabetes, high cholesterol, and synuclein bodies)

3. Autoimmune cross-targeting hypothesis:  The Cross-targeting of simultaneous infections on one tissue, one infection inside and one infections outside, triggers autoimmunity.  Antibodies or chemicals/drugs can replace one of the infections.  By antibodies I mean even those triggered by vaccines.  For example a flu virus inside of the pancreas and e.coli latching on to the outside could trigger type one diabetes.

4. Co-carcinogenesis: a virus and a carcinogen together cause cancer. Taking Francis Peyton Rous’ hypothesis further, the carcinogen is a polymerase inhibitor which binds the viral polymerase with higher affinity. Thus the DNA methylation state has been changed but the virus is no longer viable.  DNA damage does not cause most cancers, the interaction of carcinogens inhibiting viruses do.  Further these cancers wear the receptors that the virus  used to enter and the characteristics of the cancer will be from the receptor's pathways.

5. The Gluten hypothesis:  Barrier crossing infections are ones that can cross the intestine or the blood brain barrier causing gluten sensitivity with the hole they leave behind. This explains the gluten sensitivity of Schizophernia from T.gondii, Celiac disease from e.coli, Tourettes from staph, and crohn’s from mycobacteria.

6. Viral families use receptor families. Influenzas use dopamine receptors. HPVs use Cannabinoid receptors. Herpes viruses use estrogen and estrogen-like receptors. Flaviviruses use melanocortin receptors. Polyomaviruses use serotonin receptors.  (note that this would suggest that the ZIKA virus is using the ACTH receptor )

7. Aflatoxin like compounds cause tau bodies.  ALS and picks disease are caused by different infections but both have tau.  Both infections secrete an aflatoxin like compound.  Vitamin D is protective against it because aflatoxin uses the vit D receptor.

8. Pituitary tumors are caused by an infection releasing butyrolactones which interfere with normal GABA signals and cause the immune system to confuse nerves with the infection. (or someone taking too many GHB sleeping pills)

9.  The receptors used by a virus when triggering autoimmunity cause pathways to be activated which makes the various types of one autoimmune disease.  There are 3 types of schizophrenia which match up with the 3 receptors use by the 3 herpes viruses. (sort of a continuation of 6)

The receptor pathway triggered by a virus involved in an autoimmune disease can cause symptoms of the disease that will be distinct. Example:  The 3 types of schizophrenia has all 3 herpes virus families and each receptor activated can be matched to symptoms.  Estrogen-related receptor and disorganized symptoms for example.  3 receptors used equals 3 types of schizophrenia

10. Alzheimer's disease is caused by damage to the mitochondria: alpha-herpes family, diacetyl, inherited and linked to down syndrome, or radiation damaged mitochondria.

11. Postural orthostatic tachycardia could be caused by reoviruses and the adrenergic receptors they bind.

12.  The HLAs are mailboxes for T cells or NK cells from different areas of the cell. HLA-A is the nuclear mailbox for Tc cells. HLA-B is the mitochondria's mailbox for Tc cells. HLA-DR/DQ is the cytosol's mailbox for RNA viruses for Th cells.  HLA-C is the endoplasmic reticulum's mailbox  for NK cells. HLA-E is the Golgi, HLA-F is the lysosomes, and HLA-G is the exosomes which also trigger NK cells. 

HLA-DQ could be the cytosol's mailbox for non-encapsulated viruses there like reoviruses.   HLA-DP is the outer infection mailbox?

The TLR 7 / 9 butterfly nets for DNA in the mitochondria and nucleus trigger TGF-B1 which causes B cells to express MHC1 which are the HLA-A and HLA-B.

13. Carcinogens use certain receptors to get into cells which matches them up with specific cancers.

14. TLRs, toll like receptors, are the innane immune system of nets catching conserved molecules in a non specific way but identifying the region as well as general type of infection. Like HLAs they exist in the different areas of the cell.  When the internal viral seeking TLRs are activated the IFN matches the region they are in thus the appropriate HLA is produced helping to find the exact culprit.

15. TLRs send IFNs which tells infected cells to express the corresponding HLAs and macrophages to wear the corresponding TAMs (hands to grab infected cells) TAMS: tyro T , axl A , mer M

Nucleus/ Mito    TLR7/9   IFNalpha    HLA-A HLA-B   Mer

Endoplasmic R   TLR 8     IFNgamma or more?  HLA-C                 Axl

Golgi           TLR3      IFN lamda   HLA-D               Tyro3


( Cytosol       TLR4    IFNbeta which is not an endosome tlr and carried out by Fibroblasts for bacterial infections that enter host cells ? )

  Because an infected ER means little gets to the surface of a host cell the Natural killer cells step in here and secrete IFNgamma. (note that low levels of IFN gamma is secreted to favor MHC2)

Cytosolic viruses go through the golgi before exiting which is why they trigger TLR3.

16. More for the Co-carcinogenesis:  Nuclear viruses awaken embryonic Hervs.  They do so by methylating or demethylating DNA.  If the virus family demethylates the cancer will be aggressive while the methylating viruses are slow growing.  (Cancer occurs when a carcinogen inhibits the viral polymerase..so the virus opens the DNA up but can't use it) 

Note that the infant/child form of genetically caused cancer are for the genes that regulate these embryonic division cycles.

17. Bacterial infections will hide inside of host cells like viruses. Hypothesis:  Like the IFN cytokines there should be cytokines that signify where in the host cell they are hiding.  Mycoplasmas nest inside the ER, chlamydia hide in vacuoles, salmonella hide in the golgi, and mycobacteria sit in the cytosol.   The cytokines seem to match up the features of an infection family with where they hide inside.  

For example infections that use modulins tend to move into vacuoles when infecting the host so TLR2 triggers il-23 which then (in hypothesis 20) triggers TGF3 which repairs vacuoles.

18. Could there be 4 different types of asthma caused by different infections which could be diagnosed using cytokine patterns and the allergies present in the host.

19.  The problem concerning autism and vaccines could be solved if autism is viewed as an autoimmune disease.  The autoimmune cross-targeting hypothesis when applied to autism reveals there could be 3 different types of autism:

Group Flu and RA : frontal lobe autism
Group DTP (tetanus) and HHV6 : temporal lobe autism
Group MMR and sutterella/ campylobacteria: cerebellum autism

Two of these have been linked to vaccines the MMR and the DTP.

Combining the notion that viruses use receptors to enter cells with the notion that "parts" of a virus can set off autoimmunity on the tissue one can only conclude that what is contaminating vaccines setting off autoimmunity are the tiny pieces the virus uses to bind the receptors.  Running vaccine solutions through binding columns of the receptors could "clean " the vaccine of the one piece that triggers the autoimmunity.

20. TGF-Beta has been linked to both embryogenesis and cancer as well as the immune system.  The area an infection could be damaging causes a specific TGF-B to repair the area. First the TLR butterfly net is triggered by the infection.

TLR9 or TLR7 trigger TGF-B1 which stimulates the mitochondria to grow and smad to the nucleus for DNA repair.

 TLR2 triggers TGF-b3 because the infections that use vacuoles tend to be the same ones that use modulins, 

TLR-6 which binds lipoproteins found on gram positive bacteria and mycobacterias which divide in the cytosol triggers TGF-b2 which encourages Tcells to check the cytosol of cells,

 finally TL3 of the golgi triggers TGf-B4.  TGF-B4 stimulates growth of the golgi.

21. T h17 cells are involved in second pops.  When does this happen? When large infections move inside of host cells or viral infections are hiding inside of the mitochondria or nucleus. When the viruses are not visible in the cytosol or ER which would be visible when the host cell is popped. Thus a "second popping" must occur.

il-6 and il-23 trigger Th17 to release il-22, il-24, il-17A 

note that il-6 is a "reset all in immune respose where phagocytes and TH1 are triggered"and il-23 are released by phagocytes when they can't find the infection they are looking for

il-17a increases neutrophils

il-21 and TGF-b1 trigger the release of il-26,  il-19, and il-17F

note that TLR7/9 release TGF-b1 and macrophages release il-21 when activated by viruses

il-17F stimulates CTL

22. The type of Lambda IFN matches up with the type of virus going through the golgi. (looks like all viruses go through the golgi before exiting even when they start in different areas)

IFN lambda1 Nuclear virus
IFN lambda2 Mitochondrial virus
IFN lambda 3 cytosolic virus

23. Hypothesis: the TNF family is involved with infections of the immune system itself.  Bcells wear TNF-beta(lymphotoxin-alpha) and secrete it at the peyer patches interacting with FDC. This can be seen with viral infections that invade Bcells.  Macrophages wear TNF-c (lymphotoxin-beta)when they are infected with bacterias.  Macrophages (and other APC) secrete TNF-alpha when infected with either a virus or a bacteria. They key here is that TNF-c receptors on Mast cells switch the focus of the mast cell.  They normally secrete cytokines geared at viruses but after lymphotoxin-beta receptor activation they secrete il-6, il-4, and TNF-alpha.

24. The il-20 family hypothesis of cytokines are H+ pores leaking the H+ out of their assigned membranes (extending hypothesis 21) but I don't know...they could be functioning differently but they are "popping" infections somehow.

il-20 plasma membrane?

il-22 vacuoles
il-24 golgi
il-26 nuclear membrane
il-19 mitochondria

These are used by Th17 to pop membranes.  The il-20 cytokines could also used for differentiation for example il-19 converting Th1 to Th2.

Thinking of the T17 cells as Th17 and Tc17 helps.  TGF-b1 and il-21 which appear with nuclear and mitochondrial viral infections triggers the il-26 and il-19 pores.  While il-6 and il-23 appear and trigger Th17 with bacterias that have moved inside of cells.  

25. 25-hydroxycholesterol (25HC ) is secreted by M1 macrophages to help cells infected with cytosolic viral infections.  

The hypothesis is that 25HC doesn't just inhibit viral infections by changing the fluidity of the plasma membrane but by holding viral RNA OR by helping exosomes to form.

No evidence yet that 25HC binds RNA. However the Hydroxyl group of the 25HC could attach to the sugar phosphate backbone of RNA....possible? Exosomes are high in 25HC and CD169 has been shown to bind it.  SCS and dendritic cells have cd169.  SCS is the macrophage at the lymph that takes internal antigens and presents them to the other side.

26. CSR hormone hypothesis of the germinal center.  This is a hypothesis that extends upon another researchers' hypothesis. Hormones of the location are involved in the "class switch recombination" CSR  of antibodies.  The 3 musketeers of hormones: Insulin, Growth Hormone, and Insulin-like Growth Factor dictate which antibody : IgG1, IgA, or IgE are made by B cells interacting with FDC and TFH.  

Note that this germinal center hypothesis only involves the Bcell education of it's BCR of visible foreign matter. 

27. The 3 adaptive immune attack zones: outside of cells, inside the cytosol of cells, and inside the mitochondria or the nucleus.  The germinal center is the B memory and BCR zone while the cortex region is where T cell memory and TCR receptors are key.

The paracortex zone can be split into 2 inside zones.
Inside the cytosol is the TH1 who interacts with APC MHC2 concerning cytosol infections creating IgG2.
Inside the mitochondria and the nucleus is the Tc who looks at cells' MHC1 with internal organelles infected with viruses directly and tells the B cells to make IgG3.

Also note that these cortex zones is where the T cell education and memory matter. T cells are educated for the inside of cells. The LEC lining the lymph releases il-7  which increases the TCRs . The more the TCRs are activated the more likely a T memory cell is created.

The outside zone is where the germinal center's TFH evolves from TH2.  The TH2 pathways involve infections that are visible.  The Continued activation of the BCR determines the memory B cells.

28. The dendritic cells support the 3 adaptive zones:

The follicular dendritic cell and the lymphatic dendritic cell display antigens for the BCR for the outer zone.
The myeloid dendritic cells hold antigens in MHC2 for the cytosol zone.
The plasmacytoid dendritic cells hold antigens in MHC1 for the nuclear and mitochondria zones.

http://angelabiggs.blogspot.com/2018/05/hypothesis-dendritic-cells-match-up.html

29. T gamma delta cells function like B cells and produce gamma delta antibodies that look like IgG.  Previous researchers have postulated that they go through somatic hypermutation and predate B cells' bcr/ B cell antibodies. IgGamma delta binds mostly lipids and these cells are educated in the spleen. (seen with malaria)

30. The dependence of B cell activation on T cells' cd40 or independence of the T cell (BCR activation matches up with the location of the antigen.  Antigens from inside the cell, the cytosol or nucleus or mitochondria, are T cell dependent on cd40. Antigens on the outside of the cell activate B cells through the BCR.  

31.  NKT function as the T cells with the "lipid TCR" with gamma delta T cells to produce Gamma delta antibodies against lipids? possible?

32. Two types of CTL: Cytosol infection CTL with Fas killing and then the mito/nuclear CTL with TCR killing.