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Chapter 23: Problem 74

Which transition metal atom is present in each of the following biologically important molecules: (a) hemoglobin, (b) chlorophylls, (c) siderophores.

Short Answer

Expert verified
The transition metal atoms present in each of the biologically important molecules are: (a) Hemoglobin: Iron (Fe), (b) Chlorophylls: Magnesium (Mg), and (c) Siderophores: Iron (Fe).

Step by step solution

01

Hemoglobin: Iron (Fe)

Hemoglobin is a protein found in red blood cells responsible for transporting oxygen throughout the body. Its structure contains four heme groups, each containing an iron (Fe) atom. The iron atom is what binds to oxygen, allowing it to be carried by hemoglobin. Therefore, the transition metal atom present in hemoglobin is Iron (Fe).
02

Chlorophylls: Magnesium (Mg)

Chlorophylls are responsible for the green color in plants and play a crucial role in photosynthesis, a process where sunlight is absorbed and transformed into energy for plant growth. The structure of chlorophyll molecules contains a central Magnesium (Mg) atom, which helps capture and transfer light energy. Therefore, the transition metal atom present in chlorophylls is Magnesium (Mg).
03

Siderophores: Iron (Fe)

Siderophores are small molecules, produced by microorganisms, that help them capture and transport iron (Fe). These molecules have a high affinity for binding with iron (Fe) atoms, making it easier for the microorganism to uptake and utilize the essential nutrient. Therefore, the transition metal atom present in siderophores is Iron (Fe).

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Iron in Hemoglobin
Hemoglobin is an essential protein in our blood, vital for transporting oxygen from our lungs to tissues throughout the body. This molecule's significant role hinges on the presence of iron (Fe). Each hemoglobin molecule contains four heme groups. Within each heme group, there lies an iron atom. This iron is crucial because it binds to oxygen, forming oxyhemoglobin, which is then transported across the body.

Here's how the process works:
  • Iron's Role: The iron ion in the heme group can reversibly bind to one oxygen molecule, allowing hemoglobin to load and unload oxygen as needed.
  • Oxygen Transport: Without iron, hemoglobin wouldn't be able to capture and release oxygen efficiently, making this metal an indispensable component of the blood.
  • Binding Affinity: Iron's ability to shift between different oxidation states is what allows it to bind to and release oxygen, adapting to the body’s oxygen needs.
Understanding this, it's clear why iron in hemoglobin is so vital for sustaining life.
Magnesium in Chlorophylls
Chlorophylls are the green pigments found in plant cells, directly responsible for photosynthesis, the process by which plants convert sunlight into chemical energy. A little-known fact is that the core of chlorophyll molecules contains a magnesium (Mg) atom. This atom plays a pivotal role in capturing light energy.

Magnesium's function is facilitated in several ways:
  • Central Position: In chlorophyll, magnesium sits at the center of the chlorin ring and is crucial for stabilizing the structure.
  • Light Absorption: Magnesium is vital for the chlorophyll to effectively absorb certain wavelengths of light, which is necessary for photosynthesis to occur.
  • Energy Transfer: The magnesium atom helps in transferring the absorbed energy efficiently, resulting in the synthesis of glucose.
Without magnesium, plants wouldn't be able to produce the energy they need for growth and survival, illustrating this metal's essential role in nature.
Iron Binding in Siderophores
Siderophores are specialized molecules secreted by bacteria and other microorganisms to round up and import iron from their environment. Iron is a vital nutrient for almost all living organisms, but it's often not readily available in usable forms. That's where siderophores come into play.

Here's how they operate:
  • High Affinity Binding: Siderophores have a very high affinity for iron, meaning they can bind to it even when it's present in low concentrations.
  • Chelation: Once siderophores bind to iron, they form stable complexes, which can be easily taken up by the microorganisms.
  • Utilization: These complexes are then transported into the cells, where the iron can be used for crucial biological processes like respiration and DNA synthesis.
This ability to efficiently gather iron gives microorganisms a competitive edge in iron-poor environments, demonstrating the critical role of iron binding in siderophores.

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Most popular questions from this chapter

Although the cis configuration is known for [ \(\mathrm{Pt}^{\left.(e n) \mathrm{Cl}_{2}\right] \text {, no }}\) trans form is known. (a) Explain why the trans compound is not possible. (b) Would \(\mathrm{NH}_{2} \mathrm{CH}_{2} \mathrm{CH}_{2} \mathrm{CH}_{2} \mathrm{CH}_{2} \mathrm{NH}_{2}\) be more likely than en \(\left(\mathrm{NH}_{2} \mathrm{CH}_{2} \mathrm{CH}_{2} \mathrm{NH}_{2}\right)\) to form the trans compound? Explain.

(a) What is the difference between a monodentate ligand and a bidentate ligand? (b) How many bidentate ligands are necessary to fill the coordination sphere of a six-coordinate complex? (c) You are told that a certain molecule can serve as a tridentate ligand. Based on this statement, what do you know about the molecule? mathrm{Br}$

(c) When the coordinated water to the \(\mathrm{Zn}(\mathrm{II})\) center in carbonic anhydrase is deprotonated, what ligands are bound to the Zn(II) center? Assume the three nitrogen ligands are unaffected. (d) The \(\mathrm{F} K_{a}\) of \(\left[\mathrm{Zn}\left(\mathrm{H}_{2} \mathrm{O}\right)_{d}\right]^{2+}\) is 10 . Suggest an explanation for the difference between this \(\mathrm{pK} \mathrm{K}_{\text {and }}\) that of carbonic anhydrase. (e) Would you expect carbonic anhydrase to have a decp color, like hemoglobin and other metalion containing proteins do? Explain. Two different compounds have the formulation \(\mathrm{CoBr}\left(\mathrm{SO}_{4}\right) \cdot 5 \mathrm{NH}_{3}\). Compound \(\mathrm{A}\) is dark violet, and compound B is red-violet. When compound \(A\) is treated with \(\mathrm{AgNO}_{3}(\mathrm{Gq})\), no reaction occurs, whereas compound \(\mathrm{B}\)

One of the more famous species in coordination chemistry is the Creutz-Taube complex: It is named for the two scientists who discovered it and initially studied its properties. The central ligand is pyrazine, a planar six-membered ring with nitrogens at opposite sides. (a) How can you account for the fact that the complex, which has only neutral ligands, has an odd overall charge? (b) The metal is in a low-spin configuration in both cases. Assuming octahedral coordination, draw the d-orbital energy-level diagram for each metal. (c) In many experiments the two metal ions appear to be in exactly equivalent states. Can you think of a reason that this might appear to be so, recognizing that electrons move very rapidly compared to nuclei?

Two Fe(II) complexes are both low spin but have different ligands. A solution of one is green and a solution of the other is red. Which solution is likely to contain the complex that has the stronger-field ligand? [Section 23.6]
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