scholarly journals Insights into the Structural Organization of the I1 Inner Arm Dynein from a Domain Analysis of the 1β Dynein Heavy Chain

2000 ◽  
Vol 11 (7) ◽  
pp. 2297-2313 ◽  
Author(s):  
Catherine A. Perrone ◽  
Steven H. Myster ◽  
Raqual Bower ◽  
Eileen T. O'Toole ◽  
Mary E. Porter

To identify domains in the dynein heavy chain (Dhc) required for the assembly of an inner arm dynein, we characterized a new motility mutant (ida2-6) obtained by insertional mutagenesis.ida2-6 axonemes lack the polypeptides associated with the I1 inner arm complex. Recovery of genomic DNA flanking the mutation indicates that the defects are caused by plasmid insertion into theDhc10 transcription unit, which encodes the 1β Dhc of the I1 complex. Transformation with Dhc10 constructs encoding <20% of the Dhc can partially rescue the motility defects by reassembly of an I1 complex containing an N-terminal 1β Dhc fragment and a full-length 1α Dhc. Electron microscopic analysis reveals the location of the missing 1β Dhc motor domain within the axoneme structure. These observations, together with recent studies on the 1α Dhc, identify a Dhc domain required for complex assembly and further demonstrate that the intermediate and light chains are associated with the stem regions of the Dhcs in a distinct structural location. The positioning of these subunits within the I1 structure has significant implications for the pathways that target the assembly of the I1 complex into the axoneme and modify the activity of the I1 dynein during flagellar motility.

1997 ◽  
Vol 8 (4) ◽  
pp. 607-620 ◽  
Author(s):  
S H Myster ◽  
J A Knott ◽  
E O'Toole ◽  
M E Porter

Multiple members of the dynein heavy chain (Dhc) gene family have been recovered in several organisms, but the relationships between these sequences and the Dhc isoforms that they encode are largely unknown. To identify Dhc loci and determine the specific functions of the individual Dhc isoforms, we have screened a collection of motility mutants generated by insertional mutagenesis in Chlamydomonas. In this report, we characterize one strain, pf9-3, in which the insertion event was accompanied by a deletion of approximately 13 kb of genomic DNA within the transcription unit of the Dhc1 gene. Northern blot analysis confirms that pf9-3 is a null mutation. Biochemical and structural studies of isolated axonemes demonstrate that the pf9-3 mutant fails to assemble the I1 inner arm complex, a two-headed dynein isoform composed of two Dhcs (1 alpha and 1 beta) and three intermediate chains. To determine if the Dhc1 gene product corresponds to one of the Dhcs of the I1 complex, antibodies were generated against a Dhc1-specific peptide sequence. Immunoblot analysis reveals that the Dhc1 gene encodes the 1 alpha Dhc subunit. These studies thus, identify the first inner arm Dhc locus to be described in any organism and further demonstrate that the 1 alpha Dhc subunit plays an essential role in the assembly of the I1 inner arm complex.


1988 ◽  
Vol 107 (6) ◽  
pp. 2613-2621 ◽  
Author(s):  
M Chun ◽  
S Falkenthal

Using a combination of molecular and genetic techniques we demonstrate that Ifm(2)2 is an allele of the single-copy sarcomeric myosin heavy chain gene. Flies homozygous for this allele accumulate wild-type levels of mRNA and protein in tubular muscle of adults, but fail to accumulate detectable amounts of myosin heavy chain mRNA or protein in the indirect flight muscle. We propose that the mutation interferes with either transcription of the gene or splicing of the primary transcript in the indirect flight muscle and not in other muscle tissues. Biochemical and electron microscopic analysis of flies homozygous for this mutation has revealed that thick filament assembly is abolished in the indirect flight muscle resulting in the instability of wild-type thick filament proteins. In contrast, thin filament and Z disc assembly are marginally affected. We discuss a working hypothesis for sarcomere assembly and define and experimental approach to test the predictions of this proposed pathway for sarcomere assembly.


1999 ◽  
Vol 146 (4) ◽  
pp. 801-818 ◽  
Author(s):  
Steven H. Myster ◽  
Julie A. Knott ◽  
Katrina M. Wysocki ◽  
Eileen O'Toole ◽  
Mary E. Porter

Flagellar motility is generated by the activity of multiple dynein motors, but the specific role of each dynein heavy chain (Dhc) is largely unknown, and the mechanism by which the different Dhcs are targeted to their unique locations is also poorly understood. We report here the complete nucleotide sequence of the Chlamydomonas Dhc1 gene and the corresponding deduced amino acid sequence of the 1α Dhc of the I1 inner dynein arm. The 1α Dhc is similar to other axonemal Dhcs, but two additional phosphate binding motifs (P-loops) have been identified in the NH2- and COOH-terminal regions. Because mutations in Dhc1 result in motility defects and loss of the I1 inner arm, a series of Dhc1 transgenes were used to rescue the mutant phenotypes. Motile cotransformants that express either full-length or truncated 1α Dhcs were recovered. The truncated 1α Dhc fragments lacked the dynein motor domain, but still assembled with the 1β Dhc and other I1 subunits into partially functional complexes at the correct axoneme location. Analysis of the transformants has identified the site of the 1α motor domain in the I1 structure and further revealed the role of the 1α Dhc in flagellar motility and phototactic behavior.


1987 ◽  
Vol 247 (3) ◽  
pp. 513-518 ◽  
Author(s):  
T K Watanabe ◽  
E R Kuczmarski ◽  
J K Reddy

Myosin has been identified in a variety of non-muscle cells, and is believed to play a role in maintenance of cell shape, locomotion, cytokinesis, exocytosis and other cellular functions. In this paper we describe the purification of myosin from a pancreatic acinar-cell carcinoma of the rat which forms solid tumours, but retains many differentiated functions. The purified myosin was composed of a 200,000 Da heavy chain and two or three classes of light chains. Electron-microscopic examination of rotary-shadowed preparations revealed that individual molecules had two globular heads and a long tail measuring approx. 149 nm. The myosin was soluble in high-salt buffers and became sedimentable as the ionic strength was lowered. Examination of negative-stained preparations showed that this sedimentable myosin consisted of short, bipolar, thick filaments which had a strong tendency to aggregate in a head-to-head manner. The ATPase activity of the purified myosin was stimulated by EDTA or Ca2+, but not by Mg2+. In low ionic strength the Mg2+-dependent ATPase activity was activated by muscle f-actin. The pancreatic myosin bound to actin and could be dissociated by the addition of MgATP. Myosin purified from cells cultured in media containing [32P]Pi was phosphorylated on one of the light chains as well as the heavy chain. Thus pancreatic acinar cells contain a typical non-muscle myosin, and the subunits of this molecule are subject to post-translational modification by phosphorylation.


1994 ◽  
Vol 126 (6) ◽  
pp. 1495-1507 ◽  
Author(s):  
M E Porter ◽  
J A Knott ◽  
L C Gardner ◽  
D R Mitchell ◽  
S K Dutcher

We have characterized a group of regulatory mutations that alter the activity of the outer dynein arms. Three mutations were obtained as suppressors of the paralyzed central pair mutant pf6 (Luck, D.J.L., and G. Piperno. 1989. Cell Movement. pp. 49-60), whereas two others were obtained as suppressors of the central pair mutant pfl6. Recombination analysis and complementation tests indicate that all five mutations are alleles at the SUP-PF-1/ODA4 locus and that each allele can restore motility to radial spoke and central pair defective strains. Restriction fragment length polymorphism analysis with a genomic probe for the beta-dynein heavy chain (DHC) gene confirms that this locus is tightly linked to the beta-DHC gene. Although all five mutant sup-pf-1 alleles alter the activity of the outer dynein arm as assayed by measurements of flagellar motility, only two alleles have a discernable polypeptide defect by SDS-PAGE. We have used photolytic and proteolytic cleavage procedures to localize the polypeptide defect to an approximately 100-kD domain downstream from the last putative nucleotide binding site. This region is encoded by approximately 5 kb of genomic DNA (Mitchell, D.R., and K. Brown. 1994. J. Cell Sci. 107:653-644). PCR amplification of wild-type and mutant DNA across this region identified one PCR product that was consistently smaller in the sup-pf-1 DNA. Direct DNA sequencing of the PCR products revealed that two of the sup-pf-1 mutations are distinct, in-frame deletions. These deletions occur within a region that is predicted to encode a small alpha-helical coiled-coil domain of the beta-DHC. This domain may play a role in protein-protein interactions within the outer dynein arm. Since both the size and location of this domain have been conserved in all axonemal and cytoplasmic DHCs sequenced to date, it presumably performs a common function in all dynein isoforms.


1998 ◽  
Vol 4 (S2) ◽  
pp. 1118-1119
Author(s):  
Lisa D. Brown ◽  
Marie E. Cantino

Myosin is composed of two high-molecular weight heavy chains and four low-molecular weight hght chains. In both vertebrate and invertebrate skeletal muscle, each myosin heavy chain is associated with two myosin light chains. In skeletal muscle myosins studied by X-ray diffraction, each myosin heavy chain binds one of each of two distinct classes of hght chains. Thus, while isoform distributions may vary within and between fibers, the spatial distribution of each class of light chain should be uniform within the A band and between sarcomeres and fibers. Since no such study exists for crustacean myosin, we investigated the spatial distribution of the hght chains within the superficial flexor muscle (SFM) of the lobster, Homarus americanus, using immunoelectron microscopy. The SFM contains two classes of myosin hght chains, termed “alpha” (Mr = 21,000 to 23,500) and “beta” (Mr = 18,000 to 18,500). Immunocytochemical electron microscopic results suggest that the alpha light chains are not uniformly distributed at the subsarcomere level.


2000 ◽  
Vol 113 (14) ◽  
pp. 2521-2526 ◽  
Author(s):  
S.M. King

Dyneins contain one-three microtubule motor units that are each derived from the C-terminal globular head of a heavy chain. The N-terminal regions of the heavy chains form stems that are required for intra-dynein associations. The microtubule-binding sites are located at the terminus of a short stalk that emanates from each globular head. Recent electron microscopic analysis indicates that the dynein head has a heptameric toroidal organization. This finding is echoed by the identification of six AAA (ATPases associated with cellular activities) domains and a seventh unrelated unit within this heavy chain region. At least two of these AAA domains can bind nucleotide, although only one appears able to hydrolyze ATP. Several other AAA domain proteins exhibit a similar annular organization of six AAA units. Detailed structural information is available for several AAA proteins, including N-ethylmaleimide-sensitive vesicle-fusion protein and the RuvB motor involved in DNA migration and resolution of Holliday junctions. The resulting structural parallels allow intriguing predictions to be made concerning dynein organization and motor function.


2014 ◽  
Vol 138 (10) ◽  
pp. 1365-1380 ◽  
Author(s):  
Guillermo A. Herrera

Context.—Lesions associated with monoclonal light and heavy chains display a variety of glomerular, tubular interstitial, and vascular manifestations. While some of the entities are well recognized, including light and heavy chain deposition diseases, AL (light chain) and AH (heavy chain) amyloidosis, and light chain (“myeloma”) cast nephropathy, other lesions centered on proximal tubules are much less accurately identified, properly diagnosed, and adequately understood in terms of pathogenesis and molecular mechanisms involved. These proximal tubule–centered lesions are typically associated with monoclonal light chains and have not been reported in patients with circulating monoclonal heavy chains. Objective.—To determine the incidence of proximal tubulopathies in a series of patients with monoclonal light chain–related renal lesions and characterize them with an emphasis on clinical correlations and elucidation of molecular mechanisms involved in their pathogenesis. Design.—A study of 5410 renal biopsies with careful evaluation of light microscopic, immunofluorescence, and electron microscopic findings was conducted to identify these monoclonal light/heavy chain–related lesions. In selected cases, ultrastructural immunolabeling was performed to better illustrate and understand molecular mechanisms involved or to resolve specific diagnostic difficulties. Results.—In all, 2.5% of the biopsies were diagnosed as demonstrating renal pathology associated with monoclonal light or heavy chains. Of these, approximately 46% were classified as proximal tubule–centered lesions, also referred to as monoclonal light chain–associated proximal tubulopathies. These proximal tubulopathies were divided into 4 groups defined by characteristic immunomorphologic manifestations associated with specific clinical settings. Conclusions.—These are important lesions whose recognition in the different clinical settings is extremely important for patients' clinical management, therapeutic purposes, and prognosis. These entities have been segregated into 4 distinct variants, conceptualized morphologically and clinically. Specific mechanisms involved in their pathogenesis are proposed.


Author(s):  
F.J. Sjostrand

In the 1940's and 1950's electron microscopy conferences were attended with everybody interested in learning about the latest technical developments for one very obvious reason. There was the electron microscope with its outstanding performance but nobody could make very much use of it because we were lacking proper techniques to prepare biological specimens. The development of the thin sectioning technique with its perfectioning in 1952 changed the situation and systematic analysis of the structure of cells could now be pursued. Since then electron microscopists have in general become satisfied with the level of resolution at which cellular structures can be analyzed when applying this technique. There has been little interest in trying to push the limit of resolution closer to that determined by the resolving power of the electron microscope.


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