Photoreceptor Membrane Breakdown in the Spider Dinopis: Localisation of Acid Phosphatases

Overview

Journal Cell Tissue Res

Specialties Anatomy & Histology
Cell Biology

Date 1979 Jul 17

PMID 476810

Citations 5

Authors

A D Blest

G D Price

J Maples

Affiliations

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Abstract

The ultrastructural localisation of acid phosphatases (AcPhs) during the normal daily breakdown of rhabdomere membrane in Dinopis has been examined using beta-glycerophosphate and p-nitrophenyl phosphate as substrates. Results are related to the classification of organelles in the receptors given by Blest, Powell and Kao (1978). Weak and infrequent reactions are obtained in multivesicular bodies (mvbs) and multilamellar bodies (mlbs) derived from them. Residual bodies (rbs) begin to react strongly as they lyse. Source of AcPhs is endoplasmic reticulum which has barely differentiated towards the GERL configuration; it becomes reactive as it is incorporated into secondary lysosomes. GERL tubules, Y-bodies and vesicles respond erratically and weakly, and are also incorporated into rbs. No evidence was found for a significant participation of Golgi bodies in these processes, and acid phosphatase cytochemistry fails to reveal a topographical relationship between GERL in these cells and Golgi saccules. Coated vesicle clusters found in the predawn receptive segments are AcPh-negative; this implies that their previous identification as GERL-derived "Nebenkerne" carrying hydrolytic enzymes to newly-formed mvbs (Blest, Kao and Powell, 1978) is dubious. Isolation bodies and autophagic vacuoles enclosing other organelles in pathological receptors give strong reactions while adjacent secondary lysosomes derived from rhabdomere membrane and associated GERL give weak ones. It is concluded that rhabdomere-derived rb lysis is more tightly regulated than other autophagic processes, and it is suggested that a high degree of control is necessary in a receptor which may repeat the autophagy of a large mass of transductive membrane at least 60--100 times in the course of its working life.

Citing Articles

Extracellular shedding of photoreceptor membrane in the open rhabdom of a tipulid fly.

Williams D, Blest A Cell Tissue Res. 1980; 205(3):423-38.

PMID: 7357581 DOI: 10.1007/BF00232283.

The sources of acid hydrolases for photoreceptor membrane degradation in a grapsid crab.

Blest A, Stowe S, Price D Cell Tissue Res. 1980; 205(2):229-44.

PMID: 7357573 DOI: 10.1007/BF00234682.

A new mechanism for transitory, local endocytosis in photoreceptors of a spider, Dinopis.

Blest A, Price D Cell Tissue Res. 1981; 217(2):267-82.

PMID: 7237527 DOI: 10.1007/BF00233580.

Cytochemical localization of acid phosphatase in light- and dark-adapted eyes of a polychaete worm, Nereis limnicola.

Brandenburger J, EAKIN R Cell Tissue Res. 1985; 242(3):623-8.

PMID: 4075381 DOI: 10.1007/BF00225428.

Acyltransferase and acid hydrolase activities of the abalone photoreceptor cell.

Kataoka S, Yamamoto T Cell Tissue Res. 1985; 241(1):59-65.

PMID: 4028123 DOI: 10.1007/BF00214626.

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