Gifts For Microbio And Paleo Enthusiasts! :DD

working in a lab is cool and all but so much of your job is just waste clean up and washing dishes 💀

i complain alot when it comes to uni and my course, but not gonna lie, here on my final year i've started to fall in love with it again, the way the fascination started when i was younger and learning new things was exciting.

throughout learning it always felt like i was not built for it, that I just cannot for the life of me focus and dedicate myself on anything. and i was just doubting myself and i should change courses or drop out because I was not meant to do this. and now on my second last semester, things kinda clicked. It may be hard for me to understand and learn, but it's worth it. To see the universe in all of its beauty, its ugliness, its complexity, its charm; it's a struggle but I'll endure it for you.

and I find myself really hoping I get to continue down in the stream of sciences and contribute to something for nature and for humanity as well, or at least deepen my understanding of how this universe works and widen my view of how intricate and special this world we live in actually is, how caring it is, how every single thing is worth something, and nothing from nature is ever truly useless

Slime Molds and Intelligence

Okay, despite going into a biology related field, I only just learned about slime molds, and hang on, because it gets WILD.

This guy in the picture is called Physarum polycephalum, one of the more commonly studied types of slime mold. It was originally thought to be a fungus, though we now know it to actually be a type of protist (a sort of catch-all group for any eukaryotic organism that isn't a plant, animal, or a fungus). As protists go, it's pretty smart. It is very good at finding the most efficient way to get to a food source, or multiple food sources. In fact, placing a slime mold on a map with food sources at all of the major cities can give a pretty good idea of an efficient transportation system. Here is a slime mold growing over a map of Tokyo compared to the actual Tokyo railway system:

Pretty good, right? Though they don't have eyes, ears, or noses, the slime molds are able to sense objects at a distance kind of like a spider using tiny differences in tension and vibrations to sense a fly caught in its web. Instead of a spiderweb, though, this organism relies on proteins called TRP channels. The slime mold can then make decisions about where it wants to grow. In one experiment, a slime mold was put in a petri dish with one glass disk on one side and 3 glass disks on the other side. Even though the disks weren't a food source, the slime mold chose to grow towards and investigate the side with 3 disks over 70% of the time.

Even more impressive is that these organisms have some sense of time. If you blow cold air on them every hour on the hour, they'll start to shrink away in anticipation when before the air hits after only 3 hours.

Now, I hear you say, this is cool and all, but like, I can do all those things too. The slime mold isn't special...

To which I would like to point out that you have a significant advantage over the slime mold, seeing as you have a brain.

Yeah, these protists can accomplish all of the things I just talked about, and they just... don't have any sort of neural architecture whatsoever? They don't even have brain cells, let alone the structures that should allow them to process sensory information and make decisions because of it. Nothing that should give them a sense of time. Scientists literally have no idea how this thing is able to "think'. But however it does, it is sure to be a form of cognition that is completely and utterly different from anything that we're familiar with.

NaH + H2O = NaOH + H2

(via Myco-heterotrophic plant (Thismia calcarata) | Photo from th… | Flickr)

🧪The sodium-potassium pump🧬

Greetings, Tumblr community! 🧠💡 Let's engage in a comprehensive exploration of the sodium-potassium pump, dissecting its molecular intricacies and elucidating its critical role in cellular homeostasis.

Introduction:

The sodium-potassium pump, residing within the cellular membrane, is an adenosine triphosphate (ATP)-dependent transmembrane protein pivotal for maintaining ionic balance. Its primary function is to actively transport three sodium ions out of the cell while concurrently importing two potassium ions.

Functional Mechanism:

In terms of mechanistic precision, the sodium-potassium pump operates as an ATPase enzyme, utilizing the energy derived from ATP hydrolysis. This primary active transport process involves sequential conformational changes within the pump's structure.

The process commences with the binding of intracellular sodium ions to high-affinity sites on the pump. Subsequent phosphorylation, facilitated by ATP, induces conformational alterations that render the pump receptive to extracellular potassium ions. This triggers dephosphorylation, allowing potassium ions to be released intracellularly.

This orchestrated ion exchange serves to uphold the electrochemical gradient across the cellular membrane, establishing and preserving the resting membrane potential. In essence, the sodium-potassium pump is the architect of the delicate balance between sodium and potassium concentrations.

Physiological Significance:

The physiological ramifications of this meticulous ion transport extend to neuronal excitability and osmoregulation. By contributing to the establishment of the resting membrane potential, the pump plays a pivotal role in regulating action potentials and facilitating the propagation of nerve impulses.

Additionally, the pump actively participates in cellular volume control through osmoregulation. Its influence on water movement prevents cellular swelling or shrinkage, underscoring its significance in maintaining cellular integrity.

For those seeking empirical validation, consider consulting the following authoritative sources:

1. **Alberts B, Johnson A, Lewis J, et al.** Molecular Biology of the Cell. 4th edition. New York: Garland Science; 2002. Section 11.3, The Plasma Membrane.

2. **Nelson DL, Cox MM.** Lehninger Principles of Biochemistry. 7th edition. New York: W.H. Freeman; 2017. Chapter 11, Active Transport and the Cytoskeleton.

3. **Lodish H, Berk A, Zipursky SL, et al.** Molecular Cell Biology. 4th edition. New York: W. H. Freeman; 2000. Section 15.1, The Transport of Small Molecules Across Membranes.

Immerse yourself in the scientific intricacies of cellular dynamics with these foundational resources! 📚✨

gorgeous mold in a petri dish, Sporothrix schenckii

this months herbologist reward, the verdigris agaric! to all my amazing patrons, this little mushroom postcard print with its folklore and facts is now on its way to you!

HORROR WEEK- FOTD #144 : apple bolete! (exsudoporus frostii)

the apple bolete (also frost's bolete) is a mycorrhizal fungus in the family boletaceae >:-) it typically grows near the hardwood trees of the eastern US, southern mexico & costa rica. it was chosen for horror week due to its appearance being reminiscent of muscle tissue !!

the big question : will it kill me?? nope !! however, although they are edible, they are not recommended for consumption as it is quite easy to confuse them with other red boletes. ^^

e. frostii description :

"the shape of the cap of the young fruit body ranges from a half sphere to convex, later becoming broadly convex to flat or shallowly depressed, with a diameter of 5–15 cm (2.0–5.9 in). the edge of the cap is curved inward, although as it ages it can uncurl and turn upward. in moist conditions, the cap surface is sticky as a result of its cuticle, which is made of gelatinized hyphae. if the fruit body has dried out after a rain, the cap is especially shiny, sometimes appearing finely areolate (having a pattern of block-like areas similar to cracked, dried mud). young mushrooms have a whitish bloom on the cap surface.

the colour is bright red initially, but fades with age. the flesh is up to 2.5 cm (1.0 in) thick, & ranges in colour from pallid to pale yellow to lemon yellow. the flesh has a variable staining reaction in response to bruising, so some specimens may turn deep blue almost immediately, while others turn blue weakly & slowly.

the tubes comprising the pore surface (the hymenium) are 9–15 mm deep, yellow to olivaceous yellow (mustard yellow), turning dingy blue when bruised. the pores are small (2 to 3 per mm), circular, & until old age a deep red colour that eventually becomes paler. the pore surface is often beaded with yellowish droplets when young (a distinguishing characteristic), & readily stains blue when bruised. the stipe is 4 to 12 cm (1.6 to 4.7 in) long, & 1 to 2.5 cm (0.4 to 1.0 in) thick at its apex. it is roughly equal in thickness throughout its length, though it may taper somewhat toward the top ; some specimens may appear ventricose (swollen in the middle). the stipe surface is mostly red, or yellowish near the base ; it is reticulate — characterized by ridges arranged in the form of a net-like pattern."

[images : source & source] [fungus description : source]

Hiiii!!

Could you guys please vote for my agar art in this contest? 🌿🌸

It would mean the world to me 🥹