The Nucleosome: DNA's Fancy Packaging and Party Trick!
Imagine cramming two meters of yarn into a pea-sized box. Sounds impossible, right? Well, that's the impressive feat that cells pull off every single day with DNA! They use a clever structure called the nucleosome to pack this massive genetic blueprint into the tiny nucleus.
The journey began in 1974 when Don and Ada Olins, peering through an electron microscope, spotted repeating beads – the first glimpse of nucleosomes. Roger Kornberg, building upon this observation, proposed the now-iconic "subunit theory," envisioning DNA wrapped around histone protein cores. This theory, later solidified by Pierre Oudet's term "nucleosome," laid the groundwork for further exploration. The 1980s witnessed a flurry of activity, with Aaron Klug's group using X-ray crystallography to reveal the left-handed superhelical twist of DNA around the histone octamer. But the true masterpiece arrived in 1997 when the Richmond group, armed with advanced techniques, unveiled the first near-atomic resolution crystal structure of the nucleosome. This intricate map, showcasing the precise interactions between DNA and histones, remains a cornerstone of our understanding.
The Players:
DNA: The star of the show, carrying our genetic code in the form of a double helix.
Histones: Protein spools around which DNA tightly winds. Imagine eight of them forming a core, like a mini-protein drum set.
Linker DNA: Short stretches of DNA connecting the spools, like the spaces between beads on a necklace.
The Steps:
Wrap and Roll: Picture DNA gracefully wrapping around the histone core, like thread around a spool. Each nucleosome holds about 146 base pairs of DNA, making about 1.67 turns.
Connect and Repeat: Linker DNA bridges the gap between nucleosomes, forming a "beads-on-a-string" structure. Think of it as pearls strung between the spools.
Compact and Condense: This repetitive unit folds further, creating intricate 30-nanometer fibers. Imagine these as twisted strands of pearls!
Here's the coolest part: histones aren't static. They can be chemically modified, like adding or removing phosphate groups. These modifications act like tiny flags that tell the cell how tightly to wrap the DNA, essentially throwing a "party" for specific genes by making them more accessible. This fine-tuning allows cells to respond to their environment and express the right genes at the right time. Understanding the nucleosome model is crucial for unraveling the mysteries of gene regulation and diseases like cancer. By studying how modifications affect nucleosome structure and gene access, scientists can develop new therapies to target specific genes and potentially treat diseases at the root cause.
While the nucleosome model is the foundation, the story gets even more intriguing. Different histone types and modifications create variations, influencing chromatin structure and function. Think of it as different music genres influencing the dance moves! Additionally, other proteins interact with the nucleosome, adding another layer of complexity to this fascinating choreography.
The nucleosome model is more than just a neat way to package DNA. It's a testament to the intricate dance between molecules that orchestrates life's processes. By understanding this fundamental structure, we gain deeper insights into cellular function, paving the way for advancements in medicine and beyond.
Remember, this is just the beginning! The world of nucleosomes and chromatin is vast and ever-evolving. So, keep exploring, keep questioning, and keep dancing to the rhythm of DNA!
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Hello! I am a molecular biologist, and I was wondering if I could get your opinion on some of my theories on Gallifreyans.
I haven't read through everything on your blog yet, but I'm working my way through it (lol). So some of this may not be quite accurate with what you have set up thus far.
Basically, I want to briefly discuss alternative splicing! Anyway, in metazoans, alternative splicing outcomes can be regulated in a time and tissue specific manner by legitimately hundreds of biomolecules such as RNA binding proteins, chromatin remodelers, hormones, etc etc. It is subject to epigenetic regulation as alternative splicing and transcription are coupled (and splicing largely occurs cotranscriptionally), so details such as DNA methylation, nucleosome positioning, histone modifications, etc can change the balance of different mRNA isoforms. This is largely because these factors will either help recruit splicing factors (or inhibit their recruitment) or because it will slow RNA Polymerase II elongation.
Onto my theories. I have been thinking for a little while that the lindos hormone can perhaps modulate splicing, triggering the production of regeneration-specific isoforms. Perhaps their bodies work so fast that isoforms promoting totipotency trigger a temporary transition away from the cells' differentiated states.
I also think it could be possible that they have some novel ability to, say, "unsplice," which humans cannot do. This could potentially allow them to use already made transcripts and then completely change them to produce unique proteins without needing to transcribe another mRNA. This could feasibly allow them to rapidly change what proteins are in each cell (perhaps quick enough that it occurs within the regeneration itself). Although, there would be some instability while now unused proteins get degraded or the splicing/unsplicing ratio stabilizes (the molding period). This would require intense regulation as well as unsplicing and resplicing would now be posttranscriptional, but I digress.
Sorry to bother you with the long post, I just had too many nerdy ideas going through my head. Thanks!
-gallifreyanhotfive
Molecular Biology: 'Unsplicing'
Oh, you thrill me with your biology talk! Molecular biology is not a speciality so apologies in advance for any limited response.
🔬 Lindos and Its Variations
Something to be covered in the new Anatomy and Physiology guide is a wider look at the role of Lindos in Time Lords, so we're hitting the nail on the head here.
Under stress, injury, or during the process of regeneration, the lindal gland significantly increases its production of the hormone Lindoneogen like a caffeine-fueled scientist, resulting in a corresponding surge in lindos cell production. There are several forms of lindos cells, including:
Lindopoetic Progenitor Cells (LPCs): Dormant cells that spring into action upon Lindoneogen stimulation.
Lindopoietic Stem Cells (LSCs): Residing in the yellow bone marrow, ready to differentiate under the guidance of Lindoneogen and the catalytic influence of artron, into ...
Lindoblasts and Phagolindotropes: Specialised cells responsible for regenerating tissue and recycling cellular components from the previous incarnation.
Haemolindocytes: Circulating cells that endow Gallifreyan blood with its regenerative properties.
💡Splicing and Lindoneogen
Lindoneogen could play a key role in alternative splicing, creating specific mRNA isoforms vital for regeneration. This implies that Lindoneogen is not just a cellular signal but also a molecular tool for crafting the necessary protein portfolio for regeneration. So Lindoneogen may trigger the production of specific mRNA isoforms that are vital for the regeneration process, which could lead to the expression of proteins that facilitate the transition of cells into a more pluripotent state.
🖇️Unsplicing
Love this idea. 'Unsplicing' as your concept presents would be particularly relevant during regeneration. It could allow cells to quickly alter their protein expression profiles without the lag of new mRNA transcription. This rapid adaptation would be pretty handy for the efficient transition of cells to suit the requirements of the new incarnation.
🔗Integrating with Lindos Cells
This concept of 'unsplicing' could be particularly prominent in the function of phagolindotropes. As these cells are responsible for consuming the previous incarnation’s cells and replacing them with new ones, their ability to 'unsplice' and rapidly change protein expression would be pretty useful. This mechanism might also support the functions of lindoblasts and haemolindocytes in tissue regeneration and blood adaptability.
🏫 So ...
The addition of splicing and unsplicing mechanisms to the lindos theory suggests a more complex and dynamic process than simple cellular proliferation and differentiation, with dynamic genetic adaptations at the molecular level highlighting the advanced biological capabilities of Gallifreyans. Good work, Batman!
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RNAs, introns and introduction to recombinant DNA.
The genome is a vault of genetic information, but on its own its kind of useless as the information cannot be used in the cell. Utilization of this information requires a coordinated effort from enzymes and proteins, this coordination of chemical reactions is known as genome expression. The initial step of genome expression is known as the transcriptome, a collection of RNA molecules which is made up of the genes active in the cell at the time. (its constantly changing to the environment that the cell is in) the transcriptome is maintained by transcription a simple process in which individual genes are copied and pasted into RNA molecules known as mRNA. The second product within gene expression is known as proteome which you can think of as the cells library of proteins at hand. This gives the cell its unique and individual characteristics that it can express. The proteins in this library known as the proteome are synthesized by the translation of some RNA molecules.
I think it is of utmost importance to start with the most simple and important step…
Transcription:
The first step in transcription is initiation,
Transcription begins with the binding of RNA polymerase 2 to the promoter region of a gene, the most common promotor contains a conserved gene sequence we call the TATA box, but there are many others that exist which are show by the different TF families.
The next step we have the formation of transcription initiation complex, this is when transcription factors such as TATA-binding protein also known as TBP, bind to the promoter, forming a pre-initiation complex. Other general transcription factors join, and RNA polymerase 2 is recruited to form the transcription initiation complex.
Next, we have initiation of transcription where RNA polymerase 2 unwinds the DNA helix at the transcription “start site”. The enzyme catalyses the synthesis of a short RNA primer (which is about 10 nucleotides in length) complementary to the template DNA strand.
The second step is Elongation:
Once the RNA polymerase has synthesized the initial RNA primer, it proceeds to elongate the RNA chain, The RNA polymerase adds ribonucleotide complementary to the template DNA strand. This process is known as RNA chain Elongation.
After this, we have nucleosome remodelling where the DNA in eukaryotic cells is wrapped around histone proteins to form nucleosomes. As transcription proceeds, nucleosomes are temporarily disrupted and then reassembled, allowing RNA polymerase to access the DNA template.
The third step is Termination:
Eukaryotic mRNA molecules undergo post-transcriptional modification, this includes polyadenylation which involves the addition of a poly-A tail to the 3’ end of the RNA. Polyadenylation is then accompanied by cleavage of the RNA precursor at the specific site.
During this process transcription termination signals are recognized by RNA polymerase 2, leading to its dissociation from the DNA template. The termination signal will most likely include the poly-A signal.
The fourth step being RNA processing:
The first step of RNA processing is known as “capping”. Capping the 5’ end of the newly synthesized mRNA is modified with a 7-methylguanosine cap, the whole point of this cap is just to protect the mRNA as it leaves the nucleus and helps in the transportation process.
The second step is splicing, Eukaryotic genes often contain introns (which are kind of gaps or non-coding regions) and exons (which are the important bits, coding regions). In a process called splicing the annoying useless introns are cut and the exons are then pinched together with each other. This is all catalysed by a complex of RNA and proteins known as spliceosomes.
The fifth step being transport and translation:
This is when mRNA is transported out of the nucleus to the cytoplasm where it serves as a template for translation.
The sixth step is regulation:
Gene expression if tightly regulated at the transcriptional level by various elements, including transcriptional factors and chromatin modification, there is also enhancers and silencers that help regulate elements that influence transcription.
We also have post-transcriptional regulation, which is processes such as alternative splicing and RNA stability which play roles in determining the final mRNA products.
It is important to acknowledge that Eukaryotic transcription is more complex than prokaryotic transcription due to the presence of introns, the involvement of multiple RNA polymerases, and the necessity for additional processing steps.
This diagram helps visualise the main steps more simply.
Hope this was clear excuse any mistakes in grammar :)
Referencing:
Picture link above^
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Corona from hydrogen
Corona from hydrogen
Small water grown from outside
This is the story
Rocky gas, icy and smoky
Animals and humans are also complex but
A miracle similar to life
Animals and humans are also complex but
A miracle similar to life
Corona from hydrogen
Small water grown from outside
This is the story
Rocky gas, icy and smoky
Animals and humans are also complex but
A miracle similar to life
Animals and humans are also complex but
A miracle similar to life
hydrogen atom proton electron
Oxygen atom fuses and becomes stable
Chromosomes which are XX XY and YY
female male impotent like whatever in life
Hydrogen's action in water, in clouds
Similarly, X chromosome is impatient in X and Y
Hydrogen's action in water, in clouds
Similarly, X chromosome is impatient in X and Y
hydrogen atom proton electron
Oxygen atom fuses and becomes stable
Chromosomes which are XX XY and YY
female male impotent like whatever in life
Hydrogen's action in water, in clouds
Similarly, X chromosome is impatient in X and Y
Hydrogen's action in water, in clouds
Similarly, X chromosome is impatient in X and Y
Corona from hydrogen
Small water grown from outside
This is the story
Rocky gas, icy and smoky
Animals and humans are also complex but
A miracle similar to life
Animals and humans are also complex but
A miracle similar to life
Corona from hydrogen
Small water grown from outside
This is the story
Rocky gas, icy and smoky
Animals and humans are also complex but
A miracle similar to life
Animals and humans are also complex but
A miracle similar to life
Just like proton electron is very mobile and active but neutron is patient and stable. Similarly, egg having XX and XY chromosomes is very mobile and active. But YY which is not there at all, which is an error, is actually inactive. Do not think that just like hydrogen, the atom itself is active. In the same way, perhaps the egg also gets fertilized by the sperm. Fertilization does not happen without ovary. Sperm is not hydrogen, friends, yes, but hydrogen is a part of it. Perhaps that is why, in ovary having XX chromosomes, sperm having XY chromosomes and sperm having YY chromosomes may get fertilized. It is said that embryo having XY chromosomes is male. Embryo having XX chromosomes is female. YY chromosomes are not mobile. If it happens, then it is due to some error. Perhaps it is called eunuch. What is this chromosome? Chromosome is a package of DNA which contains some or the whole part of the genetic material of an organism. In most chromosomes, very long thin DNA fibers are covered by packaging proteins that form nucleosomes; the most important of these proteins in eukaryotic cells are histones. Wikipedia
Why are chromosomes identified as XY?
In most cases, females are XX and males are XY. Each individual must have at least one X chromosome. Since the female is XX, each egg she ovulates has an X chromosome. The male, being XY, can produce two kinds of sperm: half have an X chromosome, half have a Y.
What is this electron doing in hydrogen?
The electron in the hydrogen atom revolves around the nucleus in a circular orbit. The energy of the electron in the orbit is proportional to its distance from the nucleus. The farther the electron is from the nucleus, the greater its energy. Only a limited number of orbitals with certain energies are allowed.
We understand protons, electrons and neutrons
But why is it called XY chromosome instead of AB or 12 chromosome in the chromosome?
Human X and Y chromosomes determine the biological sex of a person, with XX specifying female and XY specifying male. Although the Y chromosome contains a small region of similarity to the X chromosome so that they can pair during meiosis, the Y chromosome is much shorter and contains many fewer genes.
Chromosome Abnormalities Fact Sheet
National Human Genome Research Institute (.gov)
https://www.genome.gov › about-genomics › Chromos...
15 Aug 2020 — Chromosome abnormalities can either be numerical or structural and usually occur when there is an error in cell division.
Genes and Chromosomes - MSD Manual Consumer Version
MSD Manuals
https://www.msdmanuals.com › ... › Genetics
A chromosome is made of a very long strand of DNA and contains many genes (hundreds to thousands). The genes on each chromosome are arranged in a particular sequence, and each gene has a particular location on the chromosome (called its locus). The form of the gene that occupies the same locus on each chromosome of a pair (one inherited from the mother and one from the father) is called an allele. In addition to DNA, chromosomes contain other chemical components that influence gene function.
Pairing
Except for certain cells (for example, sperm and egg cells or red blood cells), the nucleus of every normal human cell contains 23 pairs of chromosomes, for a total of 46 chromosomes. Normally, each pair consists of one chromosome from the mother and one from the father.
There are 22 pairs of nonsex (autosomal) chromosomes and one pair of sex chromosomes. Paired nonsex chromosomes are, for practical purposes, identical in size, shape, and position and number of genes. Because each member of a pair of nonsex chromosomes contains one of each corresponding gene, there is in a sense a backup for the genes on those chromosomes.
The 23rd pair is the sex chromosomes (X and Y).
Corona from hydrogen
Small water grown from outside
This is the story
Rocky gas, icy and smoky
Animals and humans are also complex but
A miracle similar to life
Animals and humans are also complex but
A miracle similar to life
Corona from hydrogen
Small water grown from outside
This is the story
Rocky gas, icy and smoky
Animals and humans are also complex but
A miracle similar to life
Animals and humans are also complex but
A miracle similar to life
hydrogen atom proton electron
Oxygen atom fuses and becomes stable
Chromosomes which are XX XY and YY
female male impotent like whatever in life
Hydrogen's action in water, in clouds
Similarly, X chromosome is impatient in X and Y
Hydrogen's action in water, in clouds
Similarly, X chromosome is impatient in X and Y
hydrogen atom proton electron
Oxygen atom fuses and becomes stable
Chromosomes which are XX XY and YY
female male impotent like whatever in life
Hydrogen's action in water, in clouds
Similarly, X chromosome is impatient in X and Y
Hydrogen's action in water, in clouds
Similarly, X chromosome is impatient in X and Y
Corona from hydrogen
Small water grown from outside
This is the story
Rocky gas, icy and smoky
Animals and humans are also complex but
A miracle similar to life
Animals and humans are also complex but
A miracle similar to life
Corona from hydrogen
Small water grown from outside
This is the story
Rocky gas, icy and smoky
Animals and humans are also complex but
A miracle similar to life
Animals and humans are also complex but
A miracle similar to life
Translate Hindi
हाइड्रोजन में से कोरोना
बाहरी ओर से उगाए स्मलवटर
इसी में ही है कहानी
चट्टानी गैस बर्फीले और धुंआधार
पशु इंसान भी जटिल मगर
जीवन जैसी कुछ ऐसी ही चमत्कार
पशु इंसान भी जटिल मगर
जीवन जैसी कुछ ऐसी ही चमत्कार
हाइड्रोजन में से कोरोना
बाहरी ओर से उगाए स्मलवटर
इसी में ही है कहानी
चट्टानी गैस बर्फीले और धुंआधार
पशु इंसान भी जटिल मगर
जीवन जैसी कुछ ऐसी ही चमत्कार
पशु इंसान भी जटिल मगर
जीवन जैसी कुछ ऐसी ही चमत्कार
हाइड्रोजन की एटम प्रोटोन इलेक्ट्रान
ऑक्सीजन की एटम में संगम और स्थिर
क्रोमोसोम जो एक्सएक्स एक्सवाई वाईवाई
नारी पुरुष नामर्द जैसे जीवन में जो भीर
हाइड्रोजन की क्रिया पानी में भी बादल में भी
वैसे ही एक्स क्रोमोसोम एक्स और वाई में अधीर
हाइड्रोजन की क्रिया पानी में भी बादल में भी
वैसे ही एक्स क्रोमोसोम एक्स और वाई में अधीर
हाइड्रोजन की एटम प्रोटोन इलेक्ट्रान
ऑक्सीजन की एटम में संगम और स्थिर
क्रोमोसोम जो एक्सएक्स एक्सवाई वाईवाई
नारी पुरुष नामर्द जैसे जीवन में जो भीर
हाइड्रोजन की क्रिया पानी में भी बादल में भी
वैसे ही एक्स क्रोमोसोम एक्स और वाई में अधीर
हाइड्रोजन की क्रिया पानी में भी बादल में भी
वैसे ही एक्स क्रोमोसोम एक्स और वाई में अधीर
हाइड्रोजन में से कोरोना
बाहरी ओर से उगाए स्मलवटर
इसी में ही है कहानी
चट्टानी गैस बर्फीले और धुंआधार
पशु इंसान भी जटिल मगर
जीवन जैसी कुछ ऐसी ही चमत्कार
पशु इंसान भी जटिल मगर
जीवन जैसी कुछ ऐसी ही चमत्कार
हाइड्रोजन में से कोरोना
बाहरी ओर से उगाए स्मलवटर
इसी में ही है कहानी
चट्टानी गैस बर्फीले और धुंआधार
पशु इंसान भी जटिल मगर
जीवन जैसी कुछ ऐसी ही चमत्कार
पशु इंसान भी जटिल मगर
जीवन जैसी कुछ ऐसी ही चमत्कार
जैसे प्रोटोन इलेक्ट्रान काफी गतिशील और क्रियाशील होता है लेकिन निउट्रान धैर्यपूर्ण और स्थिर होता है
उसी तरह एक्सएक्स और एक्सवाई क्रोमोसोम वाली डिम्बाणु शु्राणु काफी गतिशील और क्रियाशील होता है
मगर वाईवाई जो होता ही नहीं है जो त्रुटि है वास्तव में क्रियाहिन है
आप यह न समझ लेना दोस्तों हाइड्रोजन जैसे खुद ही एटोमिक क्रियाशील है
उसी तरह शायद इंपोर्टेंट भी शुक्राणु द्वारा निषेचित होते होंगे
निषेचन बिना ओवरी होता नहीं है
शुक्राणु हाइड्रोजन नहीं है दोस्तों हाँ मगर हाइड्रोजन जैसी की ही एक अंश है
शायद इसीलिए एक्स एक्स क्रोमोसोम वाली ओवरी में एक्स वाई क्रोमोसोम वाले शुक्राणु की वाई वाई क्रोमोसोम वाली एरर निषेचन बन जाते होंगे
कहते है
एक्स वाई क्रोमोसोम वाली भ्रूण मेल होता है
एक्स एक्स क्रोमोसोम वाली भ्रूण फिमेल
वाई वाई क्रोमोसोम सचराचर होते नहीं है अगर होता है तो कुछ त्रूटि के कारण होता है शायद इसे हिजड़ा कहा जाता होगा
यह क्रोमोसोम क्या है
गुणसूत्र डीएनए का एक पैकेज है जिसमें किसी जीव की आनुवंशिक सामग्री का कुछ या पूरा भाग होता है। अधिकांश गुणसूत्रों में, बहुत लंबे पतले डीएनए फाइबर न्यूक्लियोसोम बनाने वाले पैकेजिंग प्रोटीन से ढके होते हैं; यूकेरियोटिक कोशिकाओं में इन प्रोटीनों में सबसे महत्वपूर्ण हिस्टोन होते हैं। विकिपीडिया
क्रोमोसोम को एक्स वाई में ही क्यों पहचाना जाता है
ज़्यादातर मामलों में, मादा XX होती है और नर XY होता है। हर व्यक्ति में कम से कम एक X गुणसूत्र होना चाहिए। चूँकि मादा XX होती है, इसलिए उसके हर अंडे में एक X गुणसूत्र होता है। नर, XY होने के कारण, दो तरह के शुक्राणु उत्पन्न कर सकता है: आधे में X गुणसूत्र होता है, आधे में Y।
हाइड्रोजन में यह इलेक्ट्रान का कैरेक्टर क्या कर रहा है
हाइड्रोजन परमाणु में इलेक्ट्रॉन नाभिक के चारों ओर एक गोलाकार कक्षा में घूमता है। कक्षा में इलेक्ट्रॉन की ऊर्जा नाभिक से उसकी दूरी के समानुपाती होती है। इलेक्ट्रॉन नाभिक से जितना दूर होगा, उसकी ऊर्जा उतनी ही अधिक होगी। केवल कुछ निश्चित ऊर्जा वाली सीमित संख्या में कक्ष��ओं की अनुमति है।
प्रोटोन इलेक्ट्रॉन निउट्रान हमें समझ आता है
मगर यह क्रोमोसोम में ए बी या 1 2 गुणसुत्र न होकर एक्स वाई गुणसुत्र क्यों कहा जाता है
मानव X और Y गुणसूत्र व्यक्ति के जैविक लिंग का निर्धारण करते हैं, जिसमें XX महिला और XY पुरुष को निर्दिष्ट करता है। हालाँकि Y गुणसूत्र में X गुणसूत्र के साथ समानता का एक छोटा सा क्षेत्र होता है ताकि वे अर्धसूत्रीविभाजन के दौरान जोड़ी बना सकें, Y गुणसूत्र बहुत छोटा होता है और इसमें बहुत कम जीन होते हैं।
गुणसूत्र असामान्यताएँ तथ्य पत्रक
राष्ट्रीय मानव जीनोम अनुसंधान संस्थान (.gov)
https://www.genome.gov › about-genomics › Chromos...
15 अगस्त 2020 — गुणसूत्र असामान्यताएँ संख्यात्मक या संरचनात्मक हो सकती हैं और आमतौर पर तब होती हैं जब कोशिका विभाजन में कोई त्रुटि होती है।
जीन और गुणसूत्र - MSD मैनुअल उपभोक्ता संस्करण
MSD मैनुअल
https://www.msdmanuals.com › ... › आनुवंशिकी
एक गुणसूत्र DNA के बहुत लंबे स्ट्रैंड से बना होता है और इसमें कई जीन (सैकड़ों से हज़ारों) होते हैं। प्रत्येक गुणसूत्र पर जीन एक विशेष क्रम में व्यवस्थित होते हैं, और प्रत्येक जीन का गुणसूत्र पर एक विशेष स्थान होता है (जिसे उसका स्थान कहा जाता है)। जीन का वह रूप जो एक जोड़ी के प्रत्येक गुणसूत्र (एक माता से विरासत में मिला और एक पिता से) पर एक ही स्थान पर रहता है, उसे एलील कहा जाता है। डीएनए के अलावा, गुणसूत्रों में अन्य रासायनिक घटक होते हैं जो जीन फ़ंक्शन को प्रभावित करते हैं।
जोड़ी बनाना
कुछ कोशिकाओं (उदाहरण के लिए, शुक्राणु और अंडाणु कोशिकाएँ या लाल रक्त कोशिकाएँ) को छोड़कर, प्रत्येक सामान्य मानव कोशिका के नाभिक में 23 जोड़े गुणसूत्र होते हैं, कुल 46 गुणसूत्र होते हैं। आम तौर पर, प्रत्येक जोड़ी में माँ से एक गुणसूत्र और पिता से एक गुणसूत्र होता है।
गैर-लिंग (ऑटोसोमल) गुणसूत्रों के 22 जोड़े और सेक्स गुणसूत्रों का एक जोड़ा होता है। जोड़े गए गैर-लिंग गुणसूत्र, व्यावहारिक उद्देश्यों के लिए, आकार, आकृति और स्थिति और जीन की संख्या में समान होते हैं। क्योंकि गैर-लिंग गुणसूत्रों की एक जोड़ी के प्रत्येक सदस्य में प्रत्येक संगत जीन में से एक होता है, इसलिए एक तरह से उन गुणसूत्रों पर जीन के लिए एक बैकअप होता है।
23वीं जोड़ी सेक्स गुणसूत्र (X और Y) है।
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क्रोमोसोम जो एक्सएक्स एक्सवाई वाईवाई
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हाइड्रोजन की क्रिया पानी में भी बादल में भी
वैसे ही एक्स क्रोमोसोम एक्स और वाई में अधीर
हाइड्रोजन की क्रिया पानी में भी बादल में भी
वैसे ही एक्स क्रोमोसोम एक्स और वाई में अधीर
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पशु इंसान भी जटिल मगर
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