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A Re-examination Of Proximodistal Patterning During Vertebrate Limb Development.

Home
A Re-examination Of Proximodistal Patterning During Vertebrate Limb Development.

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A re-examination of proximodistal patterning during vertebrate limb development.

Andrew T Dudley¹, María A Ros, Clifford J Tabin

¹Department of Genetics, Harvard Medical School, 200 Longwood Avenue, Boston, Massachusetts 02115, USA.

|August 2, 2002

View abstract on PubMed

Summary

This summary is machine-generated.

Vertebrate limb development involves distinct domains specified early, with progenitor expansion before differentiation. Distal limb mesenchyme progressively determines to a limited range of proximodistal fates.

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Area of Science:

Developmental biology
Molecular biology
Genetics

Background:

The progress zone model explains vertebrate limb development.
It posits progressive changes in positional information within a distal limb bud zone.
This change is driven by an internal clock tied to cell location.

Purpose of the Study:

To investigate the mechanisms of vertebrate limb development.
To challenge and refine the existing progress zone model.
To understand how proximodistal patterning is established.

Main Methods:

Analysis of cell specification and determination during limb development.
Experimental manipulation of limb bud cells (details not provided in abstract).
Observation of progenitor cell behavior and differentiation pathways.

Main Results:

Limb segments are specified as distinct domains early in development.
Subsequent development involves progenitor population expansion before differentiation.
Distal limb mesenchyme progressively determines to a limited proximodistal fate range.

Conclusions:

The progress zone model may not fully explain limb development.
Early specification of distinct domains and progenitor expansion are key.
Progressive determination refines proximodistal patterning in the distal limb mesenchyme.