Nuclear Matrix-like Filaments and Fibrogranular Complexes Form through the Rearrangement of Specific Nuclear Ribonucleoproteins

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Vol. 11, Issue 5, 1547-1554, May 2000

Nuclear Matrix-like Filaments and Fibrogranular Complexes Form through the Rearrangement of Specific Nuclear Ribonucleoproteins

Jia-huai Tan,^* John C. Wooley, and Wallace M. LeStourgeon^*

^*Department of Molecular Biology, Vanderbilt University, Nashville, Tennessee 37235; and University of California San Diego, La Jolla, California 92037

The behavior of nuclear pre-mRNA-binding proteins after their nuclease and/or salt-induced release from RNA was investigated.After RNase digestion or salt extraction, two proteins that initiallyexist as tetramers (A2)₃B1 in isolated heterogeneous nuclear ribonucleoprotein(hnRNP) complexes quantitatively reassociated to form regularhelical filaments ranging in length from 100 nm to >10 µm. Inhighly magnified preparations prepared for scanning transmissionelectron microscopy, single filaments have diameters near 18 nm.In conventional negatively stained preparations viewed at lowmagnification, the diameters of the thinnest filaments range from7 to 10 nm. At protein concentrations of >0.1 mg/ml, the filamentsrapidly aggregated to form thicker filamentous networks that looklike the fibrogranular structures termed the "nuclear matrix."Like the residual material seen in nuclear matrix preparations,the hnRNP filaments were insoluble in 2 M NaCl. Filament formationis associated with, and may be dependent on, disulfide bridgeformation between the hnRNP proteins. The reducing agent 2-mercaptoethanolsignificantly attenuates filament assembly, and the residual materialthat forms is ultrastructurally distinct from the 7- to 10-nmfibers. In addition to the protein rearrangement leading to filamentformation, nearly one-third of the protein present in chromatin-clarifiednuclear extracts was converted to salt-insoluble material within1 min of digestion with RNase. These observations are consistentwith the possibility that the residual material termed the nuclearmatrix may be enriched in, if not formed by, denatured proteinsthat function in pre-mRNA packaging, processing, andtransport.

Corresponding author. E-mail address: lestouwm{at}ctrvax/vnderbilt.edu.

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