Other Functions of Nucleotides:- Adenine Nucleotides Are Components of Many Enzymes Cofactors

A variety of enzyme cofactors serving a wide range of chemical functions include adenosine as part of their structure (Fig. 8–41). They are unrelated structurally except for the presence of adenosine. In none of these cofactors does the adenosine portion participate directly in the primary function, but removal of adenosine generally results in a drastic reduction of cofactor activities. For example, removal of the adenine nucleotide (3-phosphoadenosine diphosphate) from acetoacetyl-CoA, the coenzyme A derivative of acetoacetate, re duces its reactivity as a substrate for -ketoacyl-CoA transferase (an enzyme of lipid metabolism) by a factor of 106. Although this requirement for adenosine has not been investigated in detail, it must involve the binding energy between enzyme and substrate (or cofactor) that is used both in catalysis and in stabilizing the initial enzyme-substrate complex (Chapter 6). In the case of-ketoacyl-CoA transferase, the nucleotide moiety of coenzyme A appears to be a binding “handle” that helps to pull the substrate (acetoacetyl-CoA) into the active site. Similar roles may be found for the nucleoside portion of other nucleotide cofactors. Why is adenosine, rather than some other large molecule, used in these structures? The answer here may involve a form of evolutionary economy. Adenosine is certainly not unique in the amount of potential binding energy it can contribute. The importance of adenosine probably lies not so much in some special chemical characteristic as in the evolutionary advantage of using one compound for multiple roles. Once ATP became the uni versal source of chemical energy, systems developed to synthesize ATP in greater abundance than the other nucleotides; because it is abundant, it becomes the logical choice for incorporation into a wide variety of structures. The economy extends to protein structure. A sin gle protein domain that binds adenosine can be used in a wide variety of enzymes. Such a domain, called a nucleotide-binding fold, is found in many enzymes that bind ATP and nucleotide cofactors.

FIGURE 8–41 Some coenzymes containing adenosine. The adenosine portion is shaded in light red. Coenzyme A (CoA) functions in acyl group transfer reactions; the acyl group (such as the acetyl or acetoacetyl group) is attached to the CoA through a thioester linkage to the -mercaptoethylamine moiety. NAD⁺ functions in hydride transfers, and FAD, the active form of vitamin B₂ (riboflavin), in electron transfers. Another coenzyme incorporating adenosine is 5-deoxyadenosylcobalamin, the active form of vita min B₁₂, which participates in intramolecular group transfers between adjacent carbons.

certainly not unique in the amount of potential binding energy it can contribute. The importance of adenosine probably lies not so much in some special chemical characteristic as in the evolutionary advantage of using one compound for multiple roles. Once ATP became the universal source of chemical energy, systems developed to synthesize ATP in greater abundance than the other nucleotides; because it is abundant, it becomes the logical choice for incorporation into a wide variety of structures. The economy extends to protein structure. A single protein domain that binds adenosine can be used in a wide variety of enzymes. Such a domain, called a nucleotide-binding fold, is found in many enzymes that bind ATP and nucleotide cofactors.

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المجمع العلمي ينظّم سفرة دينية لطلبة مشاريعه القرآنية في كربلاء

عبر مجلّة (تراث الجنوب) المحكّمة.. قسم شؤون المعارف يوثق إرث مدن جنوب العراق

في ذكرى تأسيسه.. متحف الكفيل يستعرض مسيرته في حفظ التراث الإنساني والإسلامي

قسم الشؤون الفكرية وجامعة ميسان يبحثان تعزيز التعاون العلمي المشترك

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الآخبار الصحية

السجائر الإلكترونية والإقلاع عن التدخين.. نتائج متباينة تثير الجدل العلمي

مصر تحقق إنجازاً دولياً جديداً في منظمة الصحة العالمية

دراسة: السباحة فعّالة أكثر من الجري في الحفاظ على صحة القلب

عامل خطر في بداية الحمل يؤخر تطور الكلام والمهارات الحركية لدى الرضع

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روسيا.. العلماء يضاعفون الاستقرار الحراري للألواح الشمسية ثلاث مرات

علماء يكشفون سر سرعة الدلافين في السباحة

سلمي أو دموي.. هكذا تنتقل السلطة في مجتمع الجرذان

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مواضيع ذات صلة

From Genomes to Proteomes:- Detection of Protein-Protein Interactions Helps to Define Cellular and Molecular Function

From Genomes to Proteomes:- Cellular Expression Patterns Can Reveal the Cellular Function of a Gene

From Genomes to Proteomes:- Sequence or Structural Relationships Provide Information on Protein Function

From Genes to Genomes:- Genome Sequences Provide the Ultimate Genetic Libraries

From Genes to Genomes:- The Polymerase Chain Reaction Amplifies Specific DNA Sequences

From Genes to Genomes:- DNA Libraries Provide Specialized Catalogs of Genetic Information

DNA Cloning: The Basics:- Alterations in Cloned Genes Produce Modified Proteins

DNA Cloning: The Basics:- Expression of Cloned Genes Produces Large Quantities of Protein

DNA Cloning: The Basics:- Specific DNA Sequences Are Detectable by Hybridization

DNA Cloning: The Basics:- Cloning Vectors Allow Amplification of Inserted DNA Segments

DNA Cloning: The Basics:- Restriction Endonucleases and DNA Ligase Yield Recombinant DNA

Other Functions of Nucleotides:- Nucleotides Carry Chemical Energy in Cells