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First published online June 14, 2002; 10.1104/pp.010960 Plant Physiol, July 2002, Vol. 129, pp. 1032-1044 Effect of Yeast CTA1 Gene Expression on Response of Tobacco Plants to Tobacco Mosaic Virus Infection1Institute of Biochemistry and Biophysics, Polish Academy of Sciences, Pawinskiego 5a, 02-106 Warsaw, Poland (A.T., M.K., J.H.); and Department of Botany, Agriculture University, Rakowiecka 26/30, 02-528 Warsaw, Poland (W.B.)
The response of tobacco (Nicotiana tabacum L. cv Xanthi-nc) plants with elevated catalase activity was studied after infection by tobacco mosaic virus (TMV). These plants contain the yeast (Saccharomyces cerevisiae) peroxisomal catalase gene CTA1 under the control of the cauliflower mosaic virus 35S promoter. The transgenic lines exhibited 2- to 4-fold higher total in vitro catalase activity than untransformed control plants under normal growth conditions. Cellular localization of the CTA1 protein was established using immunocytochemical analysis. Gold particles were detected mainly inside peroxisomes, whereas no significant labeling was detected in other cellular compartments or in the intercellular space. The physiological state of the transgenic plants was evaluated in respect to growth rate, general appearance, carbohydrate content, and dry weight. No significant differences were recorded in comparison with non-transgenic tobacco plants. The 3,3'-diaminobenzidine-stain method was applied to visualize hydrogen peroxide (H2O2) in the TMV infected tissue. Presence of H2O2 could be detected around necrotic lesions caused by TMV infection in non-transgenic plants but to a much lesser extent in the CTA1 transgenic plants. In addition, the size of necrotic lesions was significantly bigger in the infected leaves of the transgenic plants. Changes in the distribution of H2O2 and in lesion formation were not reflected by changes in salicylic acid production. In contrast to the local response, the systemic response in upper noninoculated leaves of both CTA1 transgenic and control plants was similar. This suggests that increased cellular catalase activity influences local but not systemic response to TMV infection.
Reactive oxygen species (ROS), such
as ·O2, hydrogen peroxide
(H2O2), and
·OH, are associated with a number of
physiological disorders in plants (Inzé and Van Montagu, 1995 There are many reports that indicate that catalases may play a critical
role in plant defense mechanisms (Anderson et al., 1998 Production of ROS, particularly
H2O2, during response to
abiotic stresses has also been proposed as a part of the signaling cascade leading to protection against these stresses (Doke et al.,
1994 Three classes of genes (Cat1, Cat2, and
Cat3) coding for catalase activity were isolated and
characterized in Nicotiana plumbaginifolia and other plant
species (Willekens et al., 1994b To contribute to a better understanding of the role of H2O2 in plant response to viral infection, we have constructed an expression cassette containing the yeast (Saccharomyces cerevisiae) catalase A coding sequence, under the control of the cauliflower mosaic virus (CaMV) 35S constitutive promoter and created tobacco plants that exhibited elevated levels of catalase. This study addresses the influence of peroxisomally expressed catalase on local and systemic responses to viral infection.
Yeast Catalases Are Poorly Inhibited by SA Two yeast strains that carry loss-of-function mutations in either
the CTA1 or CTT1 gene were used to measure a
possible inhibitory effect of SA on catalase activity. In the
CTA1+ctt
Transgenic Tobacco Plants Overexpressing Yeast Catalase Gene Transgenic tobacco plants with increased catalase activity were created by expressing the yeast catalase gene CTA1 under the control of the 35S CaMV promoter. The transgenic plants did not exhibit any visible morphological differences in comparison with healthy untransformed control plants under standard growth condition and under high-light intensity (16,000 lux). The presence of CTA1 RNA in three selected lines was confirmed by northern blotting (Fig. 2A). The transgenic lines were then screened by western blotting for the presence of CTA1 protein (58.5 kD) in crude extracts isolated from fully developed leaves (Fig. 2B), using specific anti-CTA1 antibodies. The total catalase activity was also measured. All three lines (CTA1/2, CTA1/3, and CTA1/4) exhibited increased levels of catalase activity that was two to four times higher than the catalase activity of untransformed control plants (Fig. 2C).
Line CTA1/4 was chosen and used in all experiments described in the following sections of this paper. The physiological state of the CTA1/4 line was assessed using markers such as the fresh weight to dry weight ratio and the carbohydrate content (Glc, Fru, Suc, and starch) of leaf tissue. No differences were observed in the weight of leaf fragments of equal area (data not shown). The ratio of dry weight to fresh weight remained constant in both CTA1-transformed and control tobacco plants. Similarly, the carbohydrate content (Glc, Fru, Suc, and starch) was unchanged in the CTA1/4 plants compared with untransformed plants. These results are shown in Figure 3.
The Activity of Tobacco Catalases Is Inhibited by SA It has been reported that catalase activities in various plant
species are inhibited by SA (Sánchez-Casas and Klessig, 1994
CTA1 Protein Is Located in Peroxisomes of Transgenic Plants Peroxisome-localized catalase A of yeast has a well-defined
targeting sequence (the so-called SKL motif) at its carboxyl terminus (Kragler et al., 1993
Defense Responses Are Impaired in CTA1 Plants Tobacco infected with a necrotizing strain (U1) of TMV is able to
mount an effective response and to limit pathogen presence to necrotic
lesions that are formed in the course of the HR. The size of such
necrotic lesions is generally used for assessment of the efficiency of
the defense response (Van Loon, 1983 CTA1/4 plants, similarly to untransformed control, responded to TMV infection with the formation of necrotic lesions. The first signs of tissue necrotization were visible on the 2nd d after infection, usually at 28 to 36 h postinoculation. Figure 6 shows typical TMV lesions on CTA1/4 plants and control plants 2, 4, and 7 d after infection with TMV. Necrotic lesions appeared on the CTA1 plants 3 to 6 h earlier, and after 48 h, a difference in diameter of lesion size could already be observed (Fig. 6). After 4 d, lesion size was significantly larger (45%) as compared with control plants. Such enlargement of lesion size was also present at 7 d postinfection, but no other macroscopically visible differences were detected between transgenic and control plants. A comparison of lesion size on leaves of untransformed tobacco plants and on the CTA1/4 plants is shown in Table I. A similar phenomenon was observed in other transgenic lines (CTA1/2, CTA1/3, and CTA1/4) expressing the CTA1 gene (data not shown).
Direct Localization of H2O2 in Tobacco Leaves The 3,3'-diaminobenzidine (DAB) staining method was employed to detect putative changes in H2O2 distribution in the transgenic CTA1 tobacco. In the experimental model used in this work, necrotic lesions begin to emerge between 26 and 32 h postinoculation. Leaves inoculated with TMV were DAB-stained to visualize areas of tissue with increased concentrations of hydrogen peroxide. To investigate early stages of lesion formation, tobacco leaves were collected 26 h postinoculation. At that time, lesions had just begun to emerge and appeared as barely visible needle marks. Leaves were incubated for 6 h in DAB solution. As shown in Figure 7, necrotic lesions on untransformed plants (Fig. 7A) were markedly stained by DAB, indicating the presence of H2O2 at the site of lesion formation. Such staining was almost completely absent on leaves of the CTA1/4 line (Fig. 7B).
Leaves were also collected at 30 h postinfection when necrotic lesions were already clearly visible and the tissue in the center had begun to collapse. They were treated with DAB as described above. Untransformed plants exhibited distinct brown rings around the lesions (Fig. 7C). This indicated the presence of high concentrations of H2O2 in the tissue around the point of necrosis formation. Figure 7D shows clearly that the necrotization of the tissue of CTA1-transgenic plants had already occurred by this time point. The external rings surrounding necroses characteristic for untransformed tobacco cv Xanthi-nc plants are not present. It should be noted that Figure 7, A and B, shows lesions in magnification different from that on Figure 7, C and D. To account for the possibility of a time shift in lesion formation between untransformed and CTA1/4 plants, DAB detection was performed at other time points from 26 to 33 h postinoculation, but no similar ring patterns could be detected in either class of plants (data not shown). Expression of Acidic PR Genes Is Affected in the CTA1 Plants The hypersensitive reaction is associated with a coordinated set of metabolic changes and the synthesis of PR proteins. They are induced specifically in pathological situations and do not only accumulate in the infected leaves but are also induced systemically and are associated with the development of systemic acquired resistance (SAR). They are generally regarded as biochemical markers of the defense response. Local expression of genes belonging to PR-1, PR-2, and PR-5 families in leaves infected with TMV was tested using northern analysis. Three fully developed leaves were inoculated with TMV and collected at 4 d postinoculation. Total RNA was isolated and analyzed with probes corresponding to the appropriate PR genes. As shown in Figure 8, the CTA1/4 line, similar to untransformed tobacco, was able to locally induce acidic isoforms of PR genes PR-1, PR-2, and PR-5, but the amount of accumulated mRNA was noticeably lower compared with untransformed control plants. The observed difference in expression was reproduced in several independent experiments. Remarkably, local expression of basic PR isoforms was unaffected in the transgenic plants, although these genes were also induced considerably as a result of TMV infection. Basic isoforms of PR genes were also slightly induced in mock-inoculated control plants, possibly as a response to some tissue damage that had occurred in the course of experimental procedures.
The SA Level Is Not Changed in the CTA1 Plants Three TMV- or mock-inoculated leaves of the CTA1/4 plants and of untransformed control plants were collected. Levels of free SA and SA glucoside were measured in these leaves by HPLC. The SA level in mock-inoculated leaves was very low in untransformed plants, and no significant change was observed in the CTA1/4 line. In the infected tissue at 48 h postinoculation, the SA level increased approximately 10-fold (Fig. 9A). No significant differences were observed in the accumulation level of SA between the CTA1/4 plants and untransformed control plants. At 96 h postinoculation, SA concentration in the infected leaf tissue further increased 2.5-fold compared with 48 h postinfection (Fig. 9B). Again, the SA level in the CTA1/4 line was comparable with that of untransformed plants. Moreover, the proportion of free SA to SA-glucoside was unchanged in the CTA1/4 line compared with untransformed plants.
SAR in the CTA1 Plants The observed differences in local defense response (increases in average necrotic lesion size and decreases in PR gene induction levels) between transgenic and wild-type plants raised the question as to whether similar changes would be observed in systemic leaves. The effectiveness of the defense response in the systemic parts of the infected plant was assessed by measuring necrotic lesion size after secondary infection. Both CTA1/4 and untransformed control tobacco plants were inoculated with TMV. Seven days post primary inoculation, upper uninoculated leaves on the same plants were infected with TMV or were mock-inoculated. The size of necrotic lesions resulting from primary or secondary infection was then measured at 7 d post secondary inoculation. Necrotic lesions were markedly reduced in the secondary infection as compared with primary infection in both CTA1/4 and control plants (Table II). In primary and secondary infections, respective necrotic lesions remained larger on leaves of the CTA1/4 line as compared with leaves of untransformed plants. The ratio of size reduction remained constant.
Another experiment was designed to check PR gene activation in systemic leaves of the CTA1/4 plants. Seven days post primary inoculation with TMV, previously uninoculated leaves on the same plants were inoculated with TMV or were mock-inoculated. Leaves were collected at 7 d after secondary inoculation, and total RNA was isolated and hybridized with probes corresponding to the acidic isoforms of tobacco PR-1 and PR-2 genes. The induction level of acidic isoforms of the PR genes was unchanged in systemic leaves that had been mock-inoculated (Fig. 10A). In contrast, when systemic leaves on plants that had been previously challenged with pathogen were inoculated with TMV, untransformed control plants exhibited much higher accumulation of PR transcripts compared with the CTA1/4 plants (Fig. 10B). The additional bands in the PR-2 panel probably represent other PR-2 genes, which had been recognized by the probe in addition to the main transcript. The results of this experiment indicate that the efficiency of SAR induction is not affected in the CTA1/4 plants.
Rüffer et al. (1995) Sánchez-Casas and Klessig (1994) The yeast gene CTA1 coding for peroxisomal catalase A was chosen for plant transformation, because the product of this gene is not significantly inhibited by SA. Because it was known that SA levels rise dramatically in tobacco as a consequence of pathogen infection, it was important that the introduction of additional catalase activity was not influenced by possible interactions with SA. Another reason for choosing the yeast catalase gene is the fact that yeast catalase is not closely related to plant catalases in terms of sequence similarity. This fact minimized the risk of the transgene being silenced, which is a frequent phenomenon observed in the construction of transgenic plants. One of the numerous selected transgenic lines that exhibited an approximately 3-fold increase in total catalase activity (CTA1/4) was chosen for detailed analysis and experiments to assess resistance against pathogen infection. Measurements of dry weight/fresh weight ratios and carbohydrate content are common markers indicating changes in plant metabolic condition. Neither of the assayed parameters was significantly different between CTA1/4 plants and untransformed tobacco cv Xanthi-nc plants (see Fig. 3). In addition, the overall appearance of the plants were unchanged. The inhibitory effect of SA on catalase activity in CTA1/4 and control
plants was different. For each concentration of SA tested, as shown in
Figure 4, we observed a constantly higher level of catalase activity of
approximately 30 to 40 mol
H2O2 min Two types of peroxisomal targeting sequences (PTS) have been
identified. The more common Type 1 PTS is a tripeptide at the C
terminus of the targeted protein, consisting of a small uncharged residue at position CTA1 catalase possesses an SKL-like PTS at its C terminus that was
shown to be active in yeast (Kragler et al., 1993 The CTA1/4 plants that exhibited elevated levels of catalase activity,
responded less efficiently to infection with a necrotizing TMV strain.
Data presented in Table I and in Figure 6 show that necrotic lesions
were significantly larger in CTA1/4 plants as compared with
untransformed control plants. This observation was confirmed in other
transgenic lines expressing the CTA1 gene. Levine et al.
(1994) Direct localization of H2O2
in the tissue demonstrated that in CTA1/4 plants, no
H2O2 accumulation could be
detected at early stages of lesion formation (Fig. 7B), whereas such
accumulation was clearly visible within lesions of untransformed
tobacco plants (Fig. 7A). At later stages, in untransformed tobacco
plants (Fig. 7C), high concentrations of hydrogen peroxide were
detected as a brown ring around developing necrotic lesions. In
contrast, in the CTA1/4 plants, no such ring or similar structure was
detected around necrotic lesions, and the overall
H2O2 accumulation in the
leaf tissue was greatly reduced (Fig. 7D). This observation clearly
indicates that transgenic plants overexpressing catalase may have
difficulties in attaining
H2O2 levels as high as in
untransformed plants during the oxidative burst. This suggests that, in
addition to membrane- and cell wall-associated enzymes (Wojtaszek,
1997 Impaired defense response to TMV infection in CTA1/4 plants coincided
with a decrease in the levels of mRNA for PR genes coding for acidic
isoforms of PR-1, PR-2, and PR-5 in the infected tissue (Fig. 8). These
genes are known to be induced by SA and during pathogen infection
(Brederode et al., 1991 In contrast to the differences observed in the infected tissue, the
expression of PR genes in the uninoculated tissue of infected plants
was unchanged or even slightly increased in the CTA1/4 line (Fig. 10).
Necrotic lesions formed after secondary TMV infection were larger on
CTA1/4 plants, but based on the ratio of the size decrease between
primary and secondary infection, the efficiency of SAR seems to be
unchanged (Table II). Therefore, the increased catalase activity
present in the CTA1/4 plants influences the dynamics and efficiency of
local but not systemic responses. These results appear to contradict
the hypothesis of Lamb and co-workers who suggested that ROS
synthesized in tissues distal to the infection site
("micro-bursts") were an indispensable part of the pathway leading
to SAR activation (Alvarez et al., 1998 Many biological processes are regulated by complex signaling networks
of modular structure (Hartwell et al., 1999
Plant Material and Growth Conditions Plants of tobacco (Nicotiana tabacum cv
Xanthi-nc), resistant to TMV, were grown in growth chambers using a
16-h period of light (22°C) and 8 h of darkness (18°C). The
light intensity was 5,000 to 6,000 lux, and the humidity was maintained
at 65%. For all experiments, 6- to 9-week-old plants were used. For
inoculation with TMV, carborundum-dusted leaves were rubbed with water
or TMV strain U1 solution (1 µg ml Construction of the 35S/CTA1 Transgenic Plants The coding region of the yeast (Saccharomyces
cerevisiae) catalase gene (CTA1) was excised
from the YEp352 plasmid (Hill et al., 1986 The Physiological State of the Transgenic Plants Dry Weight/Fresh Weight Ratio Ten fully developed leaves were taken from three 6-week-old tobacco plants at the same developmental stage, weighed, and lyophilized under vacuum for several hours. Leaves were then weighed again, and the ratio of dry weight to fresh weight was calculated.Carbohydrate Content For each preparation, 1 g of fresh leaf tissue was ground in liquid nitrogen, suspended in 80% (v/v) ethanol in 50 mM HEPES-KOH, pH 7.4, and incubated for 2 h at 37°C. The slurry was centrifuged at 14,000g for 15 min, and the supernatant was lyophilized. The dry supernatant was dissolved in 1.5 mL of 0.1 M imidazole-HCl, pH 6.9, centrifuged at 13,000g for 10 min to remove insoluble particles, and used for Glc, Fru, and Suc assays. The pellet was used for starch assay.Glc and Fru Spectrophotometric assays were performed in 1.5 mL of assay buffer (0.5 M imidazole-HCl, pH 6.9, 0.15 mM MgCl2, 0.45 mM NADP, and 1 mM ATP) at 340 nm using 20 µL of each sample. Measurements and calculations were performed as described by Stitt et al. (1989) .
Suc Suc assay was performed as described by Stitt et al. (1989) for
Glc and Fru assays, except that before assays, the samples were
incubated for 15 min at 20°C to 25°C with 0.2 unit of invertase.
Starch Starch content of each sample was measured using a commercially available reaction kit (Roche Molecular Biochemicals, Basel) following the manufacturer's protocol.Gene Expression Analysis RNA Analysis Total RNA was isolated from leaves as described previously (Linthorst et al., 1993). For northern blots, 10 or 20 µg RNA was separated on a 1% (w/v) agarose gel in 15 mM sodium
phosphate, pH 6.5, and transferred to Hybond N (Amersham,
Buckinghamshire, UK) filters. Hybridization was performed at 65°C in
250 mM sodium phosphate, pH 7, 1 mM EDTA,
7% (w/v) SDS, and 1% (w/v) bovine serum albumin (BSA) with one
of the following randomly labeled probes: (a) 1,550-bp
CTA1 cDNA (Cohen et al., 1988); (b) 900-bp acidic PR-1a
cDNA (Cutt et al., 1988); (c) 790-bp basic PR-1g cDNA
(Brederode et al., 1991 (d) 700-bp acidic PR-2d cDNA (Hennig et al.,
1993); (e) 550-bp basic PR-2 cDNA (Brederode et al., 1991); (f) 800-bp
acidic PR-5 (Brederode et al., 1991); (g) 700-bp basic PR-5 cDNA
(Brederode et al., 1991); and (h) 1,200-bp 25S rDNA.
Protein Analysis Proteins were extracted in buffer containing 50 mM Tris pH 8.0, 1 mM EDTA, 12 mM -mercaptoethanol, and 10 µg mL 1 phenylmethylsulfonyl
fluoride. Protein content was measured by the Bradford method using a
commercially available reaction kit (Bio-Rad, Hercules, CA). Extracts
were fractionated on a 12.5% (w/v) SDS-PAGE and subjected to
immunoblot analysis using a specific goat anti-CTA1 polyclonal antibody
(gift from Dr. A. Hartig) and alkaline phosphatase-conjugated anti-goat
antibodies from Roche Molecular Biochemicals. Immunoblots were
developed using the nitroblue tetrazolium/5-bromo-4-chloro-3-indolyl
phosphate colorimetric detection kit from Roche Molecular Biochemicals.
Catalase Assays Analysis of Yeast Catalase Properties Yeast strains were grown in glycerol-containing medium at 30°C overnight with shaking. Cells were washed in homogenization buffer (20 mM sodium citrate, pH 6.5, 5 mM MgSO4, 1 mM EDTA, 0.2 mM phenylmethylsulfonyl fluoride, and 1% [w/v] polyvinylpyrrolidone), frozen in liquid nitrogen, thawed on ice, and disrupted by vortexing 3 × 30 s with glass beads ( = 40 µm). Debris was
removed by centrifuging at 13,000g for 5 min at 4°C,
and the supernatants were used for catalase assays. Catalase activity
was measured as was described by Aebi (1984) in assay buffer (20 mM sodium citrate, pH 6.5, 5 mM
MgSO4, 1 mM EDTA, and 0.05% [v/v]
H2O2) by determining the absorbance change at
256 nm. Between 10 and 100 µL of extract were used for each
measurement. Measurements were taken every 10 s for 1 min and each
measurement was repeated three times. Results were standardized for the
protein concentration of each extract.
Influence of SA on Yeast Catalase Activity The inhibitory effect of SA was investigated by preparing modified assay buffer solutions containing SA at concentrations in the 0.5 to 5 mM range. Catalase activity measurements were carried out as described above. The reactions were linear in these conditions for at least 3 min after addition of extracts.Analysis of Tobacco Catalase Properties Crude extracts were prepared by grinding 2 g of fresh leaf
tissue in 10 mL of homogenization buffer. The following isolation steps
were all carried out at 4°C. The resulting homogenates were filtered
through four layers of cheesecloth and centrifuged at 40,000g for 30 min. Supernatants were transferred into
new tubes, and ammonium sulfate was added to 45% saturation (0.32 g
mL Direct Localization of H2O2 in Plant Tissue Leaves from control and transgenic tobacco plants infected with
TMV were taken 24 to 32 h postinfection, placed in 1 mg
mL Tissue Preparation and Immunogold Localization Leaf pieces from noninfected plants transformed with
CTA1 gene or with the transformation vector pGA482 alone
were fixed in 1.5% (v/v) glutaraldehyde and 2% (v/v)
formaldehyde in 0.1 M sodium cacodylate buffer, pH 7.2 (Karnowsky, 1965 Sections were processed as follows for immunogold staining on uncoated nickel grids. The sections were immersed in 20 mM Tris-buffered saline (TBS), pH 7.5, containing 0.9% (w/v) NaCl, for 30 min; immersed in 1% (w/v) BSA diluted in TBS, pH 7.5, for 1 h; incubated in goat anti-CTA1 polyclonal antibodies diluted 1/50 in TBS, pH 7.5, for 1 h; washed in TBS, pH 7.5 (three changes for 10 min each); washed in TBS, pH 7.5, containing 1% (w/v) BSA (three changes for 10 min each); incubated with gold-conjugated rabbit anti-goat IgG serum (10 nM; Sigma) diluted 1/15 in TBS, pH 8.2, containing 1% (w/v) BSA, for 1 h; washed in TBS, pH 8.2, containing 1% (w/v) BSA (three changes for 10 min each); finally washed in TBS, pH 8.2 (two changes for 10 min each), and distilled water. The sections were post-stained with 2% (v/v) aqueous uranyl acetate, for 10 min. The control test, which gave no specific immunogold labeling, involved the omission of primary antibodies from the sequence. Sections were viewed in EM 100C (JEOL, Tokyo) at 80 kV. Quantification and Characterization of SA and SAG Free SA was extracted and quantified essentially as described by
Raskin et al. (1989) Statistical Analysis Data are reported as the mean ± SD. The results were compared statistically by using a two-tailed Student's t test, and differences were considered significant if P values were <0.05. Distribution of Materials Upon request, all novel materials described in this publication will be made available in a timely manner for noncommercial purposes, subject to the requisite permission from any third-party owners of all or parts of the material. Obtaining any permission will be the responsibility of the requestor.
We thank Dr. A. Hartig for a generous gift of the anti-CTA1 polyclonal antibody; Drs. J. Bol and H. Linthorst for plasmids containing PR-1, PR-2, and PR-5 (basic) probes; Drs. J. Rytka and M. Skoneczny for thoughtful discussions; and Drs. J. Rudd and A. Kononowicz and all of our friends for critical reading of the manuscript.
Received October 19, 2001; returned for revision December 20, 2001; accepted February 21, 2002. 1 This work was supported by the State Committee for Scientific Research (grant no. 6P04A02817).
2 These authors contributed equally to the paper.
3 Present address: Bureau of Forest Planning and Geodesy, Wawelska 52/54, 00-922 Warszawa, Poland.
* Corresponding author; e-mail jacekh{at}ibb.waw.pl; fax 48-39-121623.
Article, publication date, and citation information can be found at www.plantphysiol.org/cgi/doi/10.1104/pp.010960.
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ABSTRACT
INTRODUCTION
, Glc;
, Fru; 
, Suc; 
, starch). The results are arithmetic means with
error bars representing the SD.
3, a basic residue at position