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One hundred years of chromosome research and what remains to be learned / by A. Lima-de-Faria.

By: Publication details: Dordrecht ; Boston : Kluwer Academic Publishers, 2003.Description: vii, 219 p. : ill. ; 31 cmISBN:
  • 1402014392 (hbk. : alk. paper)
Subject(s): DDC classification:
  • QU 470 F 2240 2003  F 2240 2003
Online resources:
Contents:
Contents Introduction. Part I: Nine Periods Of Chromosome Research: 1795 to 2010. First Period 1795-1850. The precursors: Better microscopes allowed reaching the cell level. Second Period 1850-1900. The pioneers: The discovery of the chromosome was a by-product of microbiology. Third Period 1900-1930. The era of abstract genetics: Order in embryonic development led to the finding of order in inheritance. Fourth Period 1930-1950. The impact of physics and chemistry on genetics: World War II encouraged the development of microbial genetics. Fifth Period 1950-1970. Radioisotopes and electron microscopy became a most fruitful combination: Molecular biology received its main impulse from disciplines outside genetics. Sixth Period 1970-1980. The mechanisms of cancer and of development were sought at the DNA level: Biotechnology emerged as a new field as genetics created its own weapons. Seventh Period 1980-1990. Neurobiology reached the molecular level: Artificial chromosomes and gene therapy became a reality. Eighth Period 1990-2001. The genome of humans and of other organisms was sequenced: The age of multilaboratory collaboration was established. Ninth Period 2001-2010. The post-genome era: The task that lies ahead. Part II: The Technology that Allowed the Study of the Chromosome: 1900 to 2001. From staining methods to DNA sequencing. Part III: In Search of the Eukaryotic Chromosome. Main stages in the discovery of the cell's structure and function. The nucleus versus the cytoplasm. Which was most important? The description of cell division: An impressive transformation was accompanied by directed cellular movements. Meiosis was another unexpected property: The cell could reduce its chromosome number. The maintenance of identity of the chromosome during interphase was accompanied by constancy and variability of pattern in different tissues. Part IV: The Three Unique Regions of the Eukaryotic Chromosome. The centromere: A Pandora's box of unearthed properties. The telomere: Not just a terminus station. The nucleolus organizer: Nothing in the cell is comparable to it. Part V: No Chromosome Can Function Outside A Cell. Cytoskeleton: A disgusting artifact became an important cell edifice. Nuclear envelope: The nucleus disclosed its outer structure. Centriole: An enigmatic cell invention. Endoplasmic reticulum and Golgi apparatus: The building of membranes permitted molecular reactions to occur in defined sequences. Cell membrane and cell wall: The cell became an individualized entity. Part VI: Specific Types Of Chromosomes. Chromosomes of viruses: An early or a late form of chromosome? Chromosomes of bacteria: Nearly naked DNA could become independent. Chromosomes of mitochondria: Intruders invaded the cell. Chromosomes of chloroplasts: Additional genomes entered the cell. Part VII: The Antithetical Properties Of The Chromosome. Physico-chemical processes are antithetical. The Chromosome's Rigidity. Maintenance of organization: The protozoan versus the human chromosome. Maintenance of the chromosome phenotype. Maintenance of gene order. Maintenance of function. The periodicity of chromosome transformations. The Chromosome's Plasticity. Structural change. Change of pattern. Change in size. Change in number. Change in function. Part VIII: Chromosome Models And What They Do Not Tell Us. The models. What the models do not tell us. Part IX: Epilogue. Where did the chromosome come from? Where is the chromosome going?
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Item type Current library Call number Copy number Status Date due Barcode
Book Open Access Book Open Access Health Sciences Library QU 470 F 2240 2003 (Browse shelf(Opens below)) 1 Available MBAL22010872

"Bibliography:" p. [185]-189.

Includes bibliographical references (p. [191]-194) and indexes.

Contents

Introduction.

Part I: Nine Periods Of Chromosome Research: 1795 to 2010.
First Period 1795-1850. The precursors: Better microscopes allowed reaching the cell level.
Second Period 1850-1900. The pioneers: The discovery of the chromosome was a by-product of microbiology.
Third Period 1900-1930. The era of abstract genetics: Order in embryonic development led to the finding of order in inheritance.
Fourth Period 1930-1950. The impact of physics and chemistry on genetics: World War II encouraged the development of microbial genetics. Fifth Period 1950-1970. Radioisotopes and electron microscopy became a most fruitful combination: Molecular biology received its main impulse from disciplines outside genetics.
Sixth Period 1970-1980. The mechanisms of cancer and of development were sought at the DNA level: Biotechnology emerged as a new field as genetics created its own weapons.
Seventh Period 1980-1990. Neurobiology reached the molecular level: Artificial chromosomes and gene therapy became a reality.
Eighth Period 1990-2001. The genome of humans and of other organisms was sequenced: The age of multilaboratory collaboration was established.
Ninth Period 2001-2010. The post-genome era: The task that lies ahead.

Part II: The Technology that Allowed the Study of the Chromosome: 1900 to 2001.
From staining methods to DNA sequencing.

Part III: In Search of the Eukaryotic Chromosome.
Main stages in the discovery of the cell's structure and function.
The nucleus versus the cytoplasm. Which was most important?
The description of cell division: An impressive transformation was accompanied by directed cellular movements.
Meiosis was another unexpected property: The cell could reduce its chromosome number.
The maintenance of identity of the chromosome during interphase was accompanied by constancy and variability of pattern in different tissues.

Part IV: The Three Unique Regions of the Eukaryotic Chromosome.
The centromere: A Pandora's box of unearthed properties.
The telomere: Not just a terminus station.
The nucleolus organizer: Nothing in the cell is comparable to it.

Part V: No Chromosome Can Function Outside A Cell.
Cytoskeleton: A disgusting artifact became an important cell edifice.
Nuclear envelope: The nucleus disclosed its outer structure.
Centriole: An enigmatic cell invention.
Endoplasmic reticulum and Golgi apparatus: The building of membranes permitted molecular reactions to occur in defined sequences.
Cell membrane and cell wall: The cell became an individualized entity.

Part VI: Specific Types Of Chromosomes.
Chromosomes of viruses: An early or a late form of chromosome?
Chromosomes of bacteria: Nearly naked DNA could become independent.
Chromosomes of mitochondria: Intruders invaded the cell.
Chromosomes of chloroplasts: Additional genomes entered the cell.

Part VII: The Antithetical Properties Of The Chromosome.
Physico-chemical processes are antithetical.
The Chromosome's Rigidity.
Maintenance of organization: The protozoan versus the human chromosome.
Maintenance of the chromosome phenotype.
Maintenance of gene order.
Maintenance of function.
The periodicity of chromosome transformations.
The Chromosome's Plasticity.
Structural change.
Change of pattern.
Change in size.
Change in number.
Change in function.

Part VIII: Chromosome Models And What They Do Not Tell Us.
The models.
What the models do not tell us.

Part IX: Epilogue.
Where did the chromosome come from?
Where is the chromosome going?

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