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DHMS 1st year Biology – YOU DOCTOR https://you-doctor.com نوٹ: اس پلیٹ فارم پر ہومیوپیتھک ادویات اور بیماریاں اور انکے کلاسیکل علاج سے متعلق معلومات صرف ہومیوپیتھک ڈاکٹرز اور سٹوڈنٹس کی رہنمائی کے لیے ہیں جو کہ سرچ بار میں کوئی بھی متعلقہ لفظ اردو زبان میں ٹائپ کرنے سے تفصیلاً آپ کے سامنے آ جائیں گی اگر پوسٹ لمبی ہو گی تو اس میں سفید باکس بنا ہوا ہو گا جس میں اس پوسٹ کے عنوان ہونگے کسی بھی مطلوبہ عنوان پر کلک کرنے سے وہ عنوان آپ کے سامنے آ جائے گا Sat, 19 Jun 2021 13:58:57 +0000 en-US hourly 1 https://wordpress.org/?v=6.7.1 https://you-doctor.com/wp-content/uploads/2021/06/cropped-IMG_20210612_163811-32x32.jpg DHMS 1st year Biology – YOU DOCTOR https://you-doctor.com 32 32 Cell information https://you-doctor.com/archives/4790 Sat, 19 Jun 2021 13:58:57 +0000 https://you-doctor.com/?p=4790 A rich variety of channels has been isolated and analyzed from a wide range of cell membranes. Invariably

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A rich variety of channels has been isolated and analyzed from a wide range of cell membranes. Invariably intrinsic proteins, they contain numerous amino acid sequences that traverse the membrane, clearly forming a specific hole, or pore. Certain channels open and close spontaneously. Some are gated, or opened, by the chemical action of a signaling substance such ascalciumacetylcholine, or glycine, whereas others are gated by changes in the electrical potential across the membrane. Channels may possess a narrow specificity, allowing passage of only potassium or sodium, or a broad specificity, allowing passage of all positively charged ions (cations) or of all negatively charged ions (anions). There are channels called gap junctions that allow the passage of molecules between pairs of cells (see below The cell matrix and cell-to-cell communication).

The gating of channels with a capacity for ion transport is the basis of the many nerve-nerve, nerve-muscle, and nerve-gland interactions underlying neurobiological behaviour. These actions depend on the electric potential of the cell membrane, which varies with the prevailing constituents in the cell’senvironment. For example, if a channel that admits only potassium ions is present in a membrane separating two different potassium chloride solutions, the positively charged potassium ions tend to flow down their concentration gradient through the channel. The negatively charged chloride ions remain behind. This separation of electric charges sets up an electric potential across the membrane called the diffusionpotential. The size of this potential depends on, among other factors, the difference in concentrations of the permeating ion across the membrane. The cell membrane in general contains the channels of widely different ion specificities, each channel contributing to the overall membrane potential according to the permeability and concentration ratio of the ion passing through it. Since the channels are often gated, the membrane’s potential is determined by which channels are open; this in turn depends on the concentrations of signaling molecules and may change with time according to the membrane potential itself.

Most cells have about a tenfold higher concentration of sodium ions outside than inside and a reverse concentration ratio of potassium ions. Free calcium ions can be 10,000 times more concentrated outside the cell than inside. Thus, sodium-, potassium-, and calcium-selective membrane channels, by allowing the diffusion of those ions past the cell membrane and causing fluctuations in the membrane’s electric potential, frequently serve as transmitters of signals from nerve cells. Ion diffusion threatens to alter the concentration of ions necessary for the cell to function. The proper distribution of ions is restored by the action of ion pumps (see below Primary active transport).

Facilitated diffusion

Many water-soluble molecules that cannot penetrate the lipid bilayer are too large to fit through open channels. In this category are sugars and amino acids. Some ions too do not diffuse through channels. These vital substances enter and leave the cell through the action of membrane transporters, which, like channels, are intrinsic proteins that traverse the cell membrane. Unlike channels, transporter molecules do not simply open holes in the membrane. Rather, they present sites on one side of the membrane to which molecules bind through chemical attraction. The binding site is highly specific, often fitting the atomic structure of only one type of molecule. When the molecule has attached to the binding site, then, in a process not fully understood, the transporter brings it through the membrane and releases it on the other side.

This action is considered a type of diffusion because the transported molecules move down their concentration gradients, from high concentration to low. To activate the action of the transporter, no other energy is needed than that of the chemical binding of the transported molecules. This action upon the transporter is similar to catalysis, except that the molecules (in this context called substrates) catalyze not a chemical reactionbut their own translocation across the cell membrane. Two such substrates are glucose and the bicarbonate ion.

The glucose transporter

This sugar-specific transport system enables half of the glucose present inside the cell to leave within four seconds at normal body temperature. The glucose transporter is clearly not a simple membrane channel. First, unlike a channel, it does not select its permeants by size, as one type of glucose is observed to move through the system a thousand times faster than its identically sized optical isomer. Second, it operates much more slowly than do most channels, moving only 1,000 molecules per second while a channel moves 1,000,000 ions. The most important difference between a membrane channel and the glucose transporter is the conformational change that the transporter undergoes while moving glucose across the membrane. Alternating between two conformations, it moves its glucose-binding site from one side of the membrane to the other. By “flipping” between its two conformational states, the transporter facilitates the diffusion of glucose; that is, it enables glucose to avoid the barrier of the cell membrane while moving spontaneously down its concentration gradient. When the concentration reaches equilibrium, net movement of glucose ceases.

facilitated diffusion system for glucose is present in many cell types. Similar systems transporting a wide range of other substrates (e.g., different sugars, amino acids, nucleosides, and ions) are also present.

The anion transporter

 

The best-studied of the facilitated diffusion systems is that which catalyzes the exchange of anions across the red blood cellmembrane. The exchange of hydroxyl for bicarbonate ions, each ion simultaneously being moved down its concentration gradient in opposite directions by the same transport molecule, is of great importance in enhancing the blood’s capacity to carry carbon dioxide from tissues to the lungs. The exchange molecule for these anions is the major intrinsic protein of red blood cells; one million of them are present on each cell, the polypeptide chain of each molecule traversing the membrane at least six times.

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حیاتیات نباتات اور حیوانات کی تعریف اور مثالیں https://you-doctor.com/archives/4640 Thu, 17 Jun 2021 10:45:22 +0000 https://you-doctor.com/?p=4640 حیاتیات یعنی بائیولوجی دو یونانی الفاظ سے مل کر بنا ہے یعنی بائی اوس بامعنی زندگی اور بامعنی

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حیاتیات یعنی بائیولوجی دو یونانی الفاظ سے مل کر بنا ہے یعنی بائی اوس بامعنی زندگی اور بامعنی بحث اس طرح بیالوجی کے معنی ایسا علم ہے جو جاندار اشیاء کے مختلف پہلوؤں سے بحث کرتا ہے حیاتیات کی دو اہم شاخیں عالم حوانات اور علم نباتات علم حیوانات ایسے علم کو کہا جاتا ہے جو جانوروں کی ساخت اور ان کے مختلف کی کارکردگی سے بحث کرتا ہے علم نباتات میں پودوں کی ساخت اور ان کے مختلف حصوں کے بارے میں بحث کی جاتی ہے نباتیات اور حیوانیات کی شاخیں مندرجہ ذیل ہیں مارفولوجی مارفولوجی میں مختلف جانداروں اور ان کے ظاہر حصوں کی شناخت کی جاتی ہے اناٹومی اناٹومی میں ٹشوز اور اعضاء کے متعلق بحث  کی جاتی ہے میں جانوروں اور پودوں کے مختلف خلیوں کی اشکال اور ان کی بیرونی اور اندرونی ساخت کا تفصیلی مطالعہ  کیا جاتا ہے اس میں خلیوں کے بننے ان کے بڑھنے  اور ان کے ختم ہونے وغیرہ نہ سے بحث جس کی جاتی ہے فزیالوجی فزیالوجی میں جانوروں اور پودوں کے اجسام کے مختلف حصوں کی کار کردگی کا مطالعہ کیا جاتا ہے امبریالوجی یہ وہ علم ہے جس میں جانوروں میں انڈے سے لے کر بچہ بننے تک اور پودوں میں پھول سے لے کر بیج بننے تک کے مختلف درجوں کے بارے میں بحث کی  جاتی ہے ایکالوجی اکالوجی میں مختلف جانوروں کے باہمی  تعلقات اور مل جل کر رہنے وغیرہ پر بحث کی جاتی ہے ٹیکسانومی جانداروں کو ایک دوسرے سے مشابہت کی بنا شناخت کرنے اور پھر ان کی جماعت بندی کرنے کے علم کو ٹیکسانومی کہا جاتا ہے جینیٹکس جانداروں کی وراثت میں نسل در نسل منتقل ہونے والی خصوصیات کے علم کو جنیٹکس کہا جاتا ہے

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