It is quite cool that photosynthesis works just like cellular respiration by producing a proton potential through chemiosmosis.
It is important to note that due to horizontal gene transfer, the early days of life, and still bacteria to this day due to bacterial conjugation, are actually a graph and not a tree, see also: Figure "Graph of life".
Definitely have a look at: coral of life representations.
TODO vs Phylogenetic tree? www.visiblebody.com/blog/phylogenetic-trees-cladograms-and-how-to-read-them:
Cladograms and phylogenetic trees are functionally very similar, but they show different things. Cladograms do not indicate time or the amount of difference between groups, whereas phylogenetic trees often indicate time spans between branching points.
Coral of life by János Podani (2019)
Source. Fantastic work!!! Some cool things we can easily see:
Mostly data driven.
Basically the same as clade.
All non-clade groups are evil. All non-clade terms must be forgotten. Some notable ones:
When a characteristic is basal, it basically means the opposite of it being polyphyletic.
E.g. monotremes laying eggs did not evolve separately after function loss, it comes directly from reptiles.
Kind of the opposite of a basal group.
Basically mean that parallel evolution happened. Some cool ones:
- homeothermy: mammals and birds
- animal flight: bats, birds and insects
- multicellularity: evolved a bunch of times
The cool thing about parallel evolution is that it shows how complex phenotype can evolve from very different initial genetic conditions, highlighting the great power of evolution.
We list some cool ones at: polyphyly.
- eol.org/ Encyclopedia of Life
Naming taxonomic ranks like genus, domain, etc. is a fucking waste of time, only useful before we developed molecular biology.
All that matters is the tree of clades with examples of species in each clade, and common characteristics shared by the clade.
And with molecular biology, we can build those trees incredibly well for extant species. When extinct species are involved however, things get more complicated.
There's six to eight in different systems of the end of the 20th century:This mess is because people don't realize that clades are all that really matter.
There's about 60 of them.
Do Bacteria Need Oxygen? by Microscope Project (2022)
Source. Shows how (persumed) aerobic bacteria flock towards an air bublle in water.Where is Anatomy Encoded in Living Systems? by Michael Levin (2022)
Source. - we are very far from full understanding. End game is a design system where you draw the body and it compiles the DNA for you.
- some cool mentions of regeneration
How genes form bodies.
Developmental Genetics 1 by Joseph Ross (2020)
Source. Talks about homeobox genes.This is hot shit, a possible worst case but sure to get there scenario to understand the brain!
Some good mentions at: Video "Where is Anatomy Encoded in Living Systems? by Michael Levin (2022)".
It is quite mind blowing when you think about it, that the huge majority of your body's cells is essentially just there to support a tiny ammount of germline, which are the only cells that can actually pass on! It is fun to imagine the cell type tree for this, with a huge branching of somatic cells, and only a few germline going forward.
One of the simplest known seems to be: en.wikipedia.org/wiki/Trichoplax
www.u-tokyo.ac.jp/focus/en/articles/a_00220.html "The simplest multicellular organism unveiled" from 2013 mentions Tetrabaena socialis.
Then of course: Caenorhabditis elegans is a relatively simple and widely studied model organism.
Nicole King (UC Berkeley, HHMI) 1: The origin of animal multicellularity by iBiology (2015)
Source. - youtu.be/1v6cgSkiHik?t=513 multicellularity is polyphyletic, e.g. evolved separately on plants, fungi and animals.
- youtu.be/1v6cgSkiHik?t=668 describes how unicellular organism choanoflagellates form colony, and how animals are characterized by certain key types of cellular interaction: adhesion, communication, regulation (cell differentiation) and extra cellular matrix production
It is hard to distinguish between colonies of unicellular organism and multicellular organism as there is a continuum between both depending on how well integrated they cells are.
From Wikipedia:and:
Multicellularity has evolved independently at least 25 times in eukaryotes
Complex multicellular organisms evolved only in six eukaryotic groups: animals, symbiomycotan fungi, brown algae, red algae, green algae, and land plants.
Anything that is not eukaryote, i.e. archaea and bacteria, see e.g.: Figure "Coral of life by János Podani (2019)".
Not a clade, and therefore a term better forgotten!
COVID happens in two stages:
- viral infection
- inflammatory phase, where the body takes over, and sometimes harms itself. It seems that people are not generally contagious at this point?
This distinction is one of the reasons why separating the virus name (SARS-CoV-2) from the disease makes sense: the disease is much broader than the viral infection.
Why is it there such a clear separation of phases?
Why do people with mild symptoms go on to die? It is a great mystery.
Ciro Santilli's theory is that COVID is extremely effective at avoiding immune response. Then, in people where this is effective, things reach a point where there is so much virus, that the body notices and moves on to take a more drastic approach. This is compatible with the virus killing older people more, as they have weaker immunes systems. This is however incompatible with the fact that people don't seem to be contagious after the viral phase is over...
There are a few possibilities:
- genetics
- bibliography:
- www.science.org/doi/10.1126/scitranslmed.abj7521 Identification of driver genes for critical forms of COVID-19 in a deeply phenotyped young patient cohort by Carapito et al. (2021)
- bibliography:
- state of the immune system based on disease history
- age
www.youtube.com/watch?v=6DxlkxA82FM COVID-19 Symposium: Entry of Coronavirus into Cells | Dr. Paul Bates
Model of Membrane Fusion by SARS CoV-2 Spike Protein by clarafi (2020)
Source. Genes list: www.ncbi.nlm.nih.gov/nuccore/MN908947.3
Some are named after the encoded protein. Others that are not as clean are just orfXXX for open reading frame XXX.
Largest gene, polyprotein that contains SARS-CoV-2 non-structural proteins 1 to 11.
Envelope.
As shown at pubmed.ncbi.nlm.nih.gov/16877062/#&gid=article-figures&pid=fig-3-uid-2 has transmembrane domain.
Membrane.
As shown at pubmed.ncbi.nlm.nih.gov/16877062/#&gid=article-figures&pid=fig-3-uid-2 has transmembrane domain.
Spike.
Nucleocapsid phosphoprotein, sticks to the RNA inside.
www.nature.com/articles/s41467-020-20768-y mentions functions:
- helps pack the viral RNA into the capsule
- also has a side function in immune suppression
These are also required for test tube replication.
Mentioned at: cen.acs.org/biological-chemistry/infectious-disease/know-novel-coronaviruss-29-proteins/98/web/2020/04
The RdRp, since this is a Positive-strand RNA virus.
Unlike SARS-CoV-2 non-structural protein, these are not needed for test tube reproduction. They must therefore be for host modulation.
Integrates its RNA genome into the host genome.
- first RNA to DNA with reverse transcriptase
- then injects DNA into host genome with integrase
Sounds complicated! The advantage is likely as in HIV: once inside the cell, it can remain hidden far away from the cell surface, but still infections.
Converts RNA to DNA, i.e. the inverse of transcription. Found in viruses such as Retrovirus, which includes e.g. HIV.
Pseudo-fuck.
Notable examples:
Structure of a Gram-negative bacteria
. Source. 
Only present in Gram-negative bacteria.
Structure of a Gram-negative bacteria
. Source. Space between the inner and bacterial outer membrane in Gram-negative bacteria
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