Your search keyword '"Sawicki, S."' showing total 19 results

1. A simulação da biomassa de aveia por elementos climáticos, nitrogênio e regulador de crescimento.

Author

Marolli, A., da Silva, J. A. G., Sawicki, S., Binelo, M. O., Scremin, A. H., Reginatto, D. C., Dornelles, E. F., and Lambrecht, D. M.

Abstract

Copyright of Arquivo Brasileiro de Medicina Veterinaria e Zootecnia is the property of Universidade Federal de Minas Gerais, Escola de Veterinaria and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2018

2. Analysis of the results and long-term follow-up of second-look laparotomy in advanced ovarian cancer.

Author

Sawicki, S., Wydra, D., Kobierski, J., Milczek, T., and Emerich, J.

Abstract

The article presents analysis on the results of 171 second-look laparotomy (SLL) and equate survival of patients having advanced ovarian cancer. The study reveals that the survival rate in patients having recurrence after negative SLL was importantly lower equated to patients with microscopic disease. It shows that probable explanation for encouraging prognosis in the group having microscopic disease was early medication of chemotherapy after SLL.

Published

2009

3. Response of the coagulation system after application of hemostatic dressings in an animal model.

Author

Jastrzębski, P., Adamiak, Z., Pomianowski, A., Krystkiewicz, W., Holak, P., Sawicki, S., Przyborowska, P., Zhalniarovich, Y., and Gudzbeler, G.

Published

2014

4. Alphavirus nsP3 functions to form replication complexes transcribing negative-strand RNA

Author

Wang, Y F, Sawicki, S G, and Sawicki, D L

Abstract

The alphavirus mutant Sindbis virus HR ts4, which has been assigned to the A complementation group, possessed a selective defect in negative-strand synthesis that was similar although not identical to that observed for the B complementation group mutant ts11 (Y.-F. Wang, S. G. Sawicki, and D. L. Sawicki, J. Virol. 65:985-988, 1991). The causal mutation was identified as a change of a C to a U residue at nucleotide 4903 in the nsP3 open reading frame that predicted a change of Ala-268 to Val. Thus, both nsP3 and nsP1 play a role selectively in the transcription of negative strands early in infection. The assignment of the mutation carried by an A complementation group mutant of Sindbis virus HR to nsP3 was unexpected, as mutations in other A complementation group mutants studied to date mapped to nsP2. Another mutant with a conditionally lethal mutation, ts7 of the G complementation group, also possessed a causal mutation resulting from a single-residue change in nsP3. Negative-strand synthesis ceased more slowly after a shift to the nonpermissive temperature in ts7-than in ts4-infected cells, and ts7 complemented ts11, but ts4 did not. However, the nsP3 of both ts4 and ts7 allowed reactivation of negative-strand synthesis by stable replication complexes containing nsP4 from ts24. Therefore, mutations in nsP3 affected only early events in replication and probably prevent the formation and/or function of the initial replication complex that synthesizes its negative-strand template. Because neither ts4 nor ts7 complemented 10A complementation group mutants, the genes for nsP2 and nsP3 function initially as a single cistron. We interpret these findings and present a model to suggest that the initial alphavirus replication complex is formed from tightly associated nsP2 and nsP3, perhaps in the form of P23, and proteolytically processed and trans-active nsP4 and nsP1.

Published

1994

5. The murine coronavirus mouse hepatitis virus strain A59 from persistently infected murine cells exhibits an extended host range

Author

Schickli, J H, Zelus, B D, Wentworth, D E, Sawicki, S G, and Holmes, K V

Abstract

In murine 17 Cl 1 cells persistently infected with murine coronavirus mouse hepatitis virus strain A59 (MHV-A59), expression of the virus receptor glycoprotein MHVR was markedly reduced (S. G. Sawicki, J. H. Lu, and K. V. Holmes, J. Virol. 69:5535-5543, 1995). Virus isolated from passage 600 of the persistently infected cells made smaller plaques on 17 Cl 1 cells than did MHV-A59. Unlike the parental MHV-A59, this variant virus also infected the BHK-21 (BHK) line of hamster cells. Virus plaque purified on BHK cells (MHV/BHK) grew more slowly in murine cells than did MHV-A59, and the rate of viral RNA synthesis was lower and the development of the viral nucleocapsid (N) protein was slower than those of MHV-A59. MHV/BHK was 100-fold more resistant to neutralization with the purified soluble recombinant MHV receptor glycoprotein (sMHVR) than was MHV-A59. Pretreatment of 17 Cl 1 cells with anti-MHVR monoclonal antibody CC1 protected the cells from infection with MHV-A59 but only partially protected them from infection with MHV/BHK. Thus, although MHV/BHK could still utilize MHVR as a receptor, its interactions with the receptor were significantly different from those of MHV-A59. To determine whether a hemagglutinin esterase (HE) glycoprotein that could bind the virions to 9-O-acetylated neuraminic acid moieties on the cell surface was expressed by MHV/BHK, an in situ esterase assay was used. No expression of HE activity was detected in 17 Cl 1 cells infected with MHV/BHK, suggesting that this virus, like MHV-A59, bound to cell membranes via its S glycoprotein. MHV/BHK was able to infect cell lines from many mammalian species, including murine (17 Cl 1), hamster (BHK), feline (Fcwf), bovine (MDBK), rat (RIE), monkey (Vero), and human (L132 and HeLa) cell lines. MHV/BHK could not infect dog kidney (MDCK I) or swine testis (ST) cell lines. Thus, in persistently infected murine cell lines that express very low levels of virus receptor MHVR and which also have and may express alternative virus receptors of lesser efficiency, there is a strong selective advantage for virus with altered interactions with receptor (D. S. Chen, M. Asanaka, F. S. Chen, J. E. Shively, and M. M. C. Lai, J. Virol. 71:1688-1691, 1997; D. S. Chen, M. Asanaka, K. Yokomori, F.-I. Wang, S. B. Hwang, H.-P. Li, and M. M. C. Lai, Proc. Natl. Acad. Sci. USA 92:12095-12099, 1995; P. Nedellec, G. S. Dveksler, E. Daniels, C. Turbide, B. Chow, A. A. Basile, K. V. Holmes, and N. Beauchemin, J. Virol. 68:4525-4537, 1994). Possibly, in coronavirus-infected animals, replication of the virus in tissues that express low levels of receptor might also select viruses with altered receptor recognition and extended host range.

Published

1997

6. Short-lived minus-strand polymerase for Semliki Forest virus

Author

Sawicki, D L and Sawicki, S G

Abstract

Semliki Forest virus (SFV)-infected BHK-21, Vero, and HeLa cells incorporated [3H]uridine into 42S and 26S plus-strand RNA and into viral minus-strand RNA (complementary to the 42S virion RNA) early in the infectious cycle. Between 3 and 4 h postinfection, the synthesis of minus-strand RNA ceased in these cultures, although the synthesis of plus-strand RNA continued at a maximal rate. At the time of cessation of minus-strand RNA synthesis, two changes in the pattern of viral protein synthesis were detected: a decrease in the translation of nonstructural proteins and an increase in the translation of the viral structural proteins. Addition of cycloheximide and puromycin to cultures of SFV-infected BHK cells actively synthesizing both viral plus- and minus-strand RNA resulted within 15 to 30 min in the selective shutoff of minus-strand RNA synthesis. Removal of the cycloheximide-containing medium led to the resumption of minus-strand synthesis and to an increased rate of viral RNA synthesis. We conclude that the minus-strand polymerase regulates the rate of SFV plus-strand RNA synthesis by determining the number of minus-strand templates and that the synthesis of the minus-strand templates is regulated at the level of translation by a mechanism which utilizes one or more short-lived polymerase proteins.

Published

1980

7. Adenovirus type 2 mRNA in transformed cells: map positions and difference in transport time

Author

Wilson, M C, Sawicki, S G, Salditt-Georgieff, M, and Darnell, J E

Abstract

Adenovirus type 2 rat transformed cells produced two polyadenylic acid-terminated mRNA's with approximate coordinates 1.5-4.4 and 4.4-11.0 on the physical map of the adenovirus type 2 genome. These mRNA's were also formed early during lytic infection in addition to one or more smaller mRNA's from the 4.4-11.0 region. In transformed cells, the 1.5-4.4 mRNA appeared in the cell cytoplasm without detectable lag, whereas the 4.4-11.0 mRNA required at least 20 to 30 min for the maximal rate of accumulation.

Published

1978

8. Specific Sindbis virus-coded function for minus-strand RNA synthesis

Author

Sawicki, D L, Sawicki, S G, Keränen, S, and Kääriäinen, L

Abstract

The synthesis of minus-strand RNA was studied in cell cultures infected with the heat-resistant strain of Sindbis virus and with temperature-sensitive (ts) belonging to complementation groups A, B, F, and G, all of which exhibited an RNA-negative (RNA-) phenotype when infection was initiated and maintained at 39 degrees C, the nonpermissive temperature. When infected cultures were shifted from 28 degrees C (the permissive temperature) to 39 degrees C at 3 h postinfection, the synthesis of viral minus-strand RNA ceased in cultures infected with ts mutants of complementation groups B and F, but continued in cultures infected with the parental virus and mutans of complementation groups A and G. In cultures infected with ts11 of complementation group B, the synthesis of viral minus-strand RNA ceased, whereas the synthesis of 42S and 26S plus-strand RNAs continued for at least 5 h after the shift to 39 degrees C. However, when ts11-infected cultures were returned to 28 degrees C 1 h after the shift to 39 degrees C, the synthesis of viral minus-strand RNA resumed, and the rate of viral RNA synthesis increased. The recovery of minus-strand synthesis translation of new proteins. We conclude that at least one viral function is required for alphavirus minus-strand synthesis that is not required for plus-strand synthesis. In cultures infected with ts6 of complementation group F, the syntheses of both viral plus-strand and minus-strand RNAs were drastically reduced after the shift to 39 degrees C. Since ts6 failed to synthesize both plus-strand and minus-strand RNAs after the shift to 39 degrees C, at least one common viral component appears to be required for the synthesis of both minus-strand and plus-strand RNAs.

Published

1981

9. A second nonstructural protein functions in the regulation of alphavirus negative-strand RNA synthesis

Author

Sawicki, D L and Sawicki, S G

Abstract

Previous studies (D.L. Sawicki, D. B. Barkhimer, S. G. Sawicki, C. M. Rice, and S. Schlesinger, Virology 174:43-52, 1990) identified a temperature-sensitive (ts) defect in Sindbis virus nonstructural protein 4 (nsP4) that reactivated negative-strand synthesis after its normal cessation at the end of the early phase of replication. We now report identification of two different ts alterations in nsP2 of Ala-517 to Thr in ts17 or Asn-700 to Lys in ts133 that also reactivated negative-strand synthesis. These same mutations caused severely reduced protease processing by nsP2 and recognition of the internal promoter for subgenomic mRNA synthesis and were responsible for the conditional lethality and RNA negativity of these mutants. Reactivation of negative-strand synthesis by mutations in nsP2 resembled that in nsP4: it was a reversible property of stable replication complexes and did not require continuation of viral protein synthesis. Recombinant viruses expressing both mutant nsP2 and nsP4 reactivated negative-strand synthesis more efficiently than did either mutant protein alone, consistent with the hypothesis that both nsP2 and nsP4 participate in template recognition. We propose that these alterations cause nsP2 and nsP4 to switch from their normal preference to recognize negative strands as templates to recognize positive strands and thereby mimic the initial formation of a replication complex.

Published

1993

10. Sindbis virus RNA-negative mutants that fail to convert from minus-strand to plus-strand synthesis: role of the nsP2 protein

Author

Dé, I, Sawicki, S G, and Sawicki, D L

Abstract

We identified mutations in the gene for nsP2, a nonstructural protein of the alphavirus Sindbis virus, that appear to block the conversion of the initial, short-lived minus-strand replicase complex (RCinitial) into mature, stable forms that are replicase and transcriptase complexes (RCstable), producing 49S genome or 26S mRNA. Base changes at nucleotide (nt) 2166 (G-->A, predicting a change of Glu-163-->Lys), at nt 2502 (G-->A, predicting a change of Val-275-->Ile), and at nt 2926 (C-->U, predicting a change of Leu-416-->Ser) in the nsP2 N domain were responsible for the phenotypes of ts14, ts16, and ts19 members of subgroup 11 (D.L. Sawicki and S.G. Sawicki, Virology 44:20-34, 1985) of the A complementation group of Sindbis virus RNA-negative mutants. Unlike subgroup I mutants, the RCstable formed at 30 degrees C transcribed 26S mRNA normally and did not synthesize minus strands in the absence of protein synthesis after temperature shift. The N-domain substitutions did not inactivate the thiol protease in the C domain of nsP2 and did not stop the proteolytic processing of the polyprotein containing the nonstructural proteins. The distinct phenotypes of subgroup I and 11 A complementation group mutants are evidence that the two domains of nsP2 are essential and functionally distinct. A detailed analysis of ts14 found that its nsPs were synthesized, processed, transported, and assembled at 40 degrees C into complexes with the properties of RCinitial and synthesized minus strands for a short time after shift to 40 degrees C. The block in the pathway to the formation of RCstable occurred after cleavage of the minus-strand replicase P123 or P23 polyprotein into mature nsP1, nsP2, nsP3, and nsP4, indicating that structures resembling RCstable, were formed at 40 degrees C. However, these RCstable or pre-RCstable structures were not capable of recovering activity at 30 degrees C. Therefore, failure to increase the rate of plus-strand synthesis after shift to 40 degrees C appears to result from failure to convert RCinitial to RCstable. We conclude that RCstable is derived from RCinitial by a conversion process and that ts14 is a conversion mutant. From their similar phenotypes, we predict that other nsP2 N-domain mutants are blocked also in the conversion of RCinitial to RCstable. Thus, the N domain of nsP2 plays an essential role in a folding pathway of the nsPs responsible for formation of the initial minus-strand replicase and for its conversion into stable plus-strand RNA-synthesizing enzymes.

Published

1996

11. Persistent infection of cultured cells with mouse hepatitis virus (MHV) results from the epigenetic expression of the MHV receptor

Author

Sawicki, S G, Lu, J H, and Holmes, K V

Abstract

The A59 strain of murine coronavirus mouse hepatitis virus (MHV) can cause persistent infection of 17C1-1 cells and other murine cell lines. Persistently infected cultures released large amounts of virus (10(7) to 10(8) PFU/ml) and were resistant to superinfection with MHV but not to infection with unrelated Semliki Forest and vesicular stomatitis viruses. The culture medium from persistently infected cultures did not contain a soluble inhibitor such as interferon that protected uninfected cells from infection by MHV or vesicular stomatitis virus. The persistent infection was cured if fewer than 100 cells were transferred during subculturing, and such cured cultures were susceptible to reinfection and the reestablishment of persistent infection. Cultures of 17C1-1 cells that had been newly cloned from single cells consisted of a mixture of MHV-resistant and -susceptible cells. 17C1-1/#97 cells, which were cured by subcloning after 97 passages of a persistently infected culture over a 1-year period, contained 5 to 10% of their population as susceptible cells, while 17C1-1/#402 cells, which were cured by subcloning after 402 passages over a 3-year period, had less than 1% susceptible cells. Susceptibility to infection correlated with the expression of MHV receptor glycoprotein (MHVR [Bgp1a]). Fluorescence-activated cell sorter analysis with antibody to MHVR showed that 17C1-1/#97 cells contained a small fraction of MHVR-expressing cells. These MHVR-expressing cells were selectively eliminated within 24 h after challenge with MHV-A59, and pretreatment of 17C1-1/#97 cells with monoclonal antibody CC1, which binds to the N-terminal domain of MHVR, blocked infection. We conclude that the subpopulation of MHVR-expressing cells were infected and killed in acutely or persistently infected cultures, while the subpopulation of MHVR-nonexpressing cells survived and proliferated. The subpopulation of MHVR-negative cells produced a small proportion of progeny cells that expressed MHVR and became infected, thereby maintaining the persistent infection as a steady-state carrier culture. Thus, in 17C1-1 cell cultures, the unstable or epigenetic expression of MHVR permitted the establishment of a persistent, chronic infection.

Published

1995

12. Coronavirus minus-strand RNA synthesis and effect of cycloheximide on coronavirus RNA synthesis

Author

Sawicki, S G and Sawicki, D L

Abstract

The temporal sequence of coronavirus plus-strand and minus-strand RNA synthesis was determined in 17CL1 cells infected with the A59 strain of mouse hepatitis virus (MHV). MHV-induced fusion was prevented by keeping the pH of the medium below pH 6.8. This had no effect on the MHV replication cycle, but gave 5- to 10-fold-greater titers of infectious virus and delayed the detachment of cells from the monolayer which permitted viral RNA synthesis to be studied conveniently until at least 10 h postinfection. Seven species of poly(A)-containing viral RNAs were synthesized at early and late times after infection, in nonequal but constant ratios. MHV minus-strand RNA synthesis was first detected at about 3 h after infection and was found exclusively in the viral replicative intermediates and was not detected in 60S single-stranded form in infected cells. Early in the replication cycle, from 45 to 65% of the [3H]uridine pulse-labeled RF core of purified MHV replicative intermediates was in minus-strand RNA. The rate of minus-strand synthesis peaked at 5 to 6 h postinfection and then declined to about 20% of the maximum rate. The addition of cycloheximide before 3 h postinfection prevented viral RNA synthesis, whereas the addition of cycloheximide after viral RNA synthesis had begun resulted in the inhibition of viral RNA synthesis. The synthesis of both genome and subgenomic mRNAs and of viral minus strands required continued protein synthesis, and minus-strand RNA synthesis was three- to fourfold more sensitive to inhibition by cycloheximide than was plus-strand synthesis.

Published

1986

13. Solubilization and immunoprecipitation of alphavirus replication complexes

Author

Barton, D J, Sawicki, S G, and Sawicki, D L

Abstract

Alphavirus replication complexes that are located in the mitochondrial fraction of infected cells which pellets at 15,000 x g (P15 fraction) were used for the in vitro synthesis of viral 49S genome RNA, subgenomic 26S mRNA, and replicative intermediates (RIs). Comparison of the polymerase activity in P15 fractions from Sindbis virus (SIN)- and Semliki Forest virus (SFV)-infected cells indicated that both had similar kinetics of viral RNA synthesis in vitro but the SFV fraction was twice as active and produced more labeled RIs than SIN. When assayed in vitro under conditions of high specific activity, which limits incorporation into RIs, at least 70% of the polymerase activity was recovered after detergent treatment. Treatment with Triton X-100 or with Triton X-100 plus deoxycholate (DOC) solubilized some prelabeled SFV RIs but little if any SFV or SIN RNA polymerase activity from large structures that also contained cytoskeletal components. Treatment with concentrations of DOC greater than 0.25% or with 1% Triton X-100-0.5% DOC in the presence of 0.5 M NaCl released the polymerase activity in a soluble form, i.e., it no longer pelleted at 15,000 x g. The DOC-solubilized replication complexes, identified by their polymerase activity in vitro and by the presence of prelabeled RI RNA, had a density of 1.25 g/ml, were 20S to 100S in size, and contained viral nsP1, nsP2, phosphorylated nsP3, nsP4, and possibly nsP34 proteins. Immunoprecipitation of the solubilized structures indicated that the nonstructural proteins were complexed together and that a presumed cellular protein of approximately 120 kDa may be part of the complex. Antibodies specific for nsP3, and to a lesser extent antibodies to nsP1, precipitated native replication complexes that retained prelabeled RIs and were active in vitro in viral RNA synthesis. Thus, antibodies to nsP3 bound but did not disrupt or inhibit the polymerase activity of replication complexes in vitro.

Published

1991

14. Sindbis virus nsP1 functions in negative-strand RNA synthesis

Author

Wang, Y F, Sawicki, S G, and Sawicki, D L

Abstract

A mutation at nucleotide 1101 of Sindbis virus ts11 nsP1 caused temperature-sensitive negative-strand synthesis and suppressed the 24R phenotype, which is caused by a mutation in nsP4. Nonstructural proteins synthesized and accumulated by ts11 at 40 degrees C did not cause the reactivation of negative-strand synthesis upon return to 30 degrees C and did not prevent the formation of new replication complexes at 30 degrees C.

Published

1991

15. Coronavirus transcription: subgenomic mouse hepatitis virus replicative intermediates function in RNA synthesis

Author

Sawicki, S G and Sawicki, D L

Abstract

Both genomic and subgenomic replicative intermediates (RIs) and replicative-form (RF) structures were found in 17CL1 mouse cells that had been infected with the A59 strain of mouse hepatitis virus (MHV), a prototypic coronavirus. Seven species of RNase-resistant RF RNAs, whose sizes were consistent with the fact that each was derived from an RI that was engaged in the synthesis of one of the seven MHV positive-strand RNAs, were produced by treatment with RNase A. Because the radiolabeling of the seven RF RNAs was proportional to that of the corresponding seven positive-strand RNAs, the relative rate of synthesis of each of the MHV positive-strand RNAs may be controlled by the relative number of each of the size classes of RIs that are produced. In contrast to alphavirus, which produced its subgenome-length RF RNAs from genome-length RIs, MHV RF RNAs were derived from genome- and subgenome-length RIs. Only the three largest MHV RF RNAs (RFI, RFII, and RFIII) were derived from the RIs that migrated slowest on agarose gels. The four smallest RF RNAs (RFIV, RFV, RFVI, and RFVII) were derived from RIs that migrated in a broad region of the gel that extended from the position of 28S rRNA to the position of the viral single-stranded MHV mRNA-3. Because all seven RIs were labeled during very short pulses with [3H]uridine, we concluded that the subgenome-length RIs are transcriptionally active. These findings, with the recent report of the presence of subgenome-length negative-strand RNAs in cells infected with porcine transmissible gastroenteritis virus (P. B. Sethna, S.-L. Hung, and D. A. Brian, Proc. Natl. Acad. Sci. USA 86: 5626-5630, 1989), strongly suggest that coronaviruses utilize a novel replication strategy that employs the synthesis of subgenomic negative strands to produce subgenomic mRNAs.

Published

1990

16. Demonstration in vitro of temperature-sensitive elongation of RNA in Sindbis virus mutant ts6

Author

Barton, D J, Sawicki, S G, and Sawicki, D L

Abstract

Characterization of conditionally lethal mutants of alphaviruses, Sindbis virus and Semliki Forest virus, has indicated that in almost all the RNA-negative mutants the temperature-sensitive (ts) defect prevents the formation of active transcription complexes at nonpermissive temperature (40 degrees C), but such complexes retain activity at 40 degrees C if formed first at permissive temperature (30 degrees C). Our recent results have extended the characterization of one exception to this finding: Sindbis ts6 transcription complexes, once formed at 30 degrees C, do not function at 40 degrees C. We used an in vitro assay for viral RNA synthesis to determine whether the ts defect was the result of dissociation of the complex or of a failure to elongate RNA chains in a stable complex. Our results indicated that the phenotype of ts6 observed in vivo was retained in vitro. In vivo incorporation into single-stranded 49S and 26S RNA was inhibited simultaneously with its incorporation into replicative intermediates upon shifting ts6-infected cells to 40 degrees C, which was compatible with a defect in elongation. Complexes formed at 30 degrees C and inactivated in vivo by shifting to 40 degrees C were reactivated by incubation in vitro at 30 degrees C but not at 40 degrees C. Thus, the transcription complexes were stable. Nascent RNA chains initiated in vivo and pulse-labeled in vitro were chased into single-stranded 49S and 26S RNA only when incubation was at 30 degrees C, indicating that the ts6 transcription complex was temperature sensitive in elongation. It should be possible to study in vitro other alphavirus RNA-negative mutants that demonstrate a change in viral RNA synthesis after shift to 40 degrees C. These would include ts mutants in the synthesis of subgenomic 26S mRNA and of minus-strand RNA.

Published

1988

17. Addition of poly(A) to nuclear RNA occurs soon after RNA synthesis.

Author

Salditt-Georgieff, M, Harpold, M, Sawicki, S, Nevins, J, and Darnell, J E

Abstract

A kinetic analysis of the appearance of [3H]uridine label in RNA sequences that neighbor poly(A), as well as the incorporation of [3H]adenosine label into both the RNA chain and the poly(A) of poly(A)-containing molecules, shows that poly(A) is added within a minute or so after RNA chain synthesis in Chinese hamster ovary cells and HeLa cells. Previous conclusions by several groups (5-7) that poly(A) might be added as long as 20-30 min after RNA synthesis appear to be in error, and the present conclusion seems much more in line with several different types of recent studies with specific mRNAs that suggest prompt poly(A) addition (13-16).

Published

1980

18. 3′-Terminal addition to HeLa cell nuclear and cytoplasmic poly(A)*1

Author

SAWICKI, S

Published

1977

19. 3′-Terminal addition to HeLa cell nuclear and cytoplasmic poly(A)*1

Author

SAWICKI, S

Published

1977