Nuclear DNA content and karyotype of Rosewood (Aniba rosaeodora)
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《遗传学和分子生物学》
ICentro Universitario Nilton Lins, Laboratorio de Biotecnologia Vegetal, Manaus, AM, Brazil
IIUniversidade Federal de Viosa, Departamento de Biologia Geral, Viosa, MG, Brazil
IIIInstituto Nacional de Pesquisas da Amaznia, Departamento de Silvicultura Tropical, Manaus, AM, Brazil
ABSTRACT
Rosewood (Aniba rosaeodora Ducke, Lauraceae) is ecologically and economically important to the Amazon region. As a consequence of its economic importance, rosewood populations have been decimated in the Amazon forest. Species of nine genera of the Lauraceae family have characterized karyotypes with n = x = 12 chromosomes in the gametophytic phase but the genus Aniba is one of the least studied Lauraceae genera with a previously undescribed genome. We used cytogenetic techniques to determine that the A. rosaeodora karyotype contained 12 pairs (2n = 24) of relatively small submetacentric chromosomes with lengths ranging from 1.34 to 2.25 mm and a nucleolar organizer region (NOR) in the short arm of chromosome 7. Flow cytometry gave 2C = 2.32 pg of DNA, equivalent to approximately 2.24 x 109 base pairs.
Key words: rosewood, Aniba rosaeodora, Lauraceae, karyotype, flow cytometry.
Introduction
The Amazon forest is mega-biodiverse but its ecosystems are still poorly known (Bawa and Seidler, 1998). Rosewood (Aniba rosaeodora Ducke, Lauraceae) is an Amazonian tree that produces an essential oil which is in great demand both in Brazil and internationally. Rosewood oil contains large amounts of linalool, a compound widely used by the cosmetics industry (Vainstein et al., 2001) but which may also have therapeutic properties as an anesthetic (Ghelardini et al., 1999) and an antimicrobial agent (Rosa et al., 2003; Inouye et al., 2001) that may lead to the development of new products. Due to commercial demand, rosewood populations have decimated in its center of origin in the Amazon forest but a small number of individual trees continue to exist in the Brazilian states of Amazonas and Para (Rosa et al., 1997).
The Lauraceae family contains 52 genera and about 2500 described species (Ribeiro et al., 1999) distributed in the tropics and subtropics, the greatest concentration of species being in the Neotropics and Southeast Asia. The chromosome number has been quantified for many species of the nine Lauraceae genera, mostly from the northern hemisphere. The characteristic gametophytic chromosome number is n = 12 but some polyploids also occur (Goldblatt and Johnson, 2000). The genera Adenodaphne (Carr and McPherson, 1986), Lindera (Wu, 1995), Machilus (Sandhu and Mann, 1988), Neolitsea (Chatha and Bir, 1987), Persea (Chen, 1993), Phoebe (Sandhu and Mann, 1988) and Sassafras (Huang et al., 1989) all possess n = 12 but the genus Litsea (Huang et al., 1988) contains five species with n = 12 and one (L. glutinous) with n = 24, while the genus Lauros has species with 2n = 12 times X, where X varies from 3 to 6 (Todua, 1987).
The only Lauraceae species to have had its nuclear DNA content quantified by flow cytometry is Persea americana, which has 2C = 1.86 pg (Arumuganathan and Earle, 1991), although Bennett and Leitch (2003) used other methods to establish that Persea indica is 2C = 3.30 and Cinnamomum camphora C = 1.80.
The genus Aniba is one of the least known members of the Lauraceae family and in spite of the great scientific, ecological and economic importance of Aniba rosaeodora its genome size, genetic structure and chromosome number and morphology have not yet been characterized. In the work described in this paper we quantified the amount of nuclear DNA in A. rosaeodora and characterized its karyotype
Material and Methods
Plant material
Amazonian rosewood (Aniba rosaeodora Ducke, Lauraceae) seeds were collected from two wild populations in reserves in the Brazilian state of Amazonas, one being the Reserva Florestal Adolpho Ducke belonging to the Brazilian National Institute for Amazonian Research (Instituto Nacional de Pesquisas da Amaznia (INPA) Manaus, Amazonas, Brazil) and the other the Silves Reserve (Associao Vida Verde (AVIVE) da Amaznia, Silves, Amazonas, Brazil). The seeds were placed in germination chambers for 15 days at 30 °C and cultivated in the INPA forest seedling greenhouse in Manaus (3°8 S, 59°52 W).
Flow Cytometry
The method used was described by Dolezel and Ghde (1995), with minor modifications. Young and vigorous seedling leaves were washed, placed in recipients containing distilled water and maintained at 4 °C. Leaf fragments (2 cm2) were macerated in 1 mL of Otto-I lysis buffer (0.1 M citric acid monohydrate plus 0.5% (v/v) Tween 20) and the suspension filtered through 40 mm pore-size membranes and transferred to clean tubes which were centrifuged at 250 g. After centrifugation the pellet containing nuclei was collected and homogenized in 100 mL of Otto-I buffer which was separated in two aliquots, one being stained with 15 mM 4’,6’-Diamidino-2-phenylindole (DAPI) solution in Otto-II buffer (0.4 mM Na2HPO4.12H2O) for 15 min in the dark and the other with 75 mM propidium iodide (PI) plus 50 mg/mL Rnase in Otto-II buffer for 30 min. The analysis of the nuclei suspension was performed using a Partec PAS II/III Flow Cytometer (Partec Gmbh, Munster, Germany). For analysis of DAPI stained nuclei we used a high pressure mercury lamp (HBO-100 W) with KG 1, BG 38 and GG 435 filters while for propidium iodide stained nuclei we used a 480 nm argon ion laser (20 mW) with TK 560 and RG 610 filters. For internal controls we used Raphanus sativus cv Saxa (2C = 1.11 pg) kindly provided by Dr Jaroslav Dolezel (Institute of Experimental Botany, Tchec Republic). Three young leaves from each of three plants and approximately 10 thousand nuclei per plant sample were analyzed using the FlowMax Partec software. Samples with coefficients of variation above 3% were not used in these analyses. The results presented in pg were transformed into base pairs as described by Bennett and Smith (1976).
Cytogenetic preparations
Thirty roots of rosewood seedlings were treated with 5 mM Oryzalin solution for 3 h at 30 °C, washed in distilled water for 15 min and fixed in 3:1 methanol:acetic acid at -20 °C. After 24 h the roots were washed and macerated in 1:10 Flaxzym:distilled water at 35 °C for 90 min. The root tips were washed in distilled water for 20 min, fixed (3x) in 3:1 methanol:acetic acid and stored at -20 °C. The cytogenetic preparations were proceeded by cellular dissociation of the apical meristem (Carvalho and Saraiva, 1997) and then left to dry at room temperature before staining with 5% Giemsa solution in phosphate buffer (pH 6.8) for 5 min, washing twice in distilled water and drying at 50 °C.
Image analysis
Twenty images of good quality metaphases per root meristem were captured using a charge-coupled device (CCD) video-camera connected to an OlympusTM BX60 microscope equipped with a 100x immersion lens. Morphological analyses of the chromosomes were performed using the Image SXM software (Rasband, 1997) running on a MacintoshTM G4 computer. The arms of each chromosome were measured in pixel units and converted to a micrometer scale. The centromeric index was determined according to the criteria for morphologic classification of chromosomes (Guerra, 1986).
Results and Discussion
Flow cytometry
The flow cytometry analysis of the nuclei suspension generated histograms with peaks corresponding to the average of the G1/G0 nuclei DNA content. The R. sativus cv Saxa peak was calibrated to channel 100 (internal standard with 2C = 1.11 pg DNA). The results from the three A. rosaeodora DAPI stained nuclei samples showed G1/G0 peaks in channels 212, 213 and 214, corresponding to a mean value of 2C = 2.36 pg DNA (Figure 1a). The equivalent samples stained with PI generated G1/G0 A. rosaeodora nuclei peaks in channels 207, 209 and 211, corresponding to a mean value of 2C = 2.32 pg DNA (Figure 1b). The two populations of rosewood showed overlaying peaks, that is, no differences in DNA content. The second DNA content measurement (2C = 2.32 pg) was calculated to be equivalent to 2.24 x 109 base pairs.
Cytogenetics
Chromosome preparations and image analysis allowed us to obtain metaphases with appropriate cytogenetic quality. After incubation in a solution (5 mM) of the herbicide Oryzalin for 3 h at 30 °C, the morphology of the chromosomes showed standard C-metaphase condensation, although in some cells the nucleolus remained attached to the secondary constriction (Figure 2). These data were used for morphologic characterization and karyogram assembly (Figure 3). The morphology of the rosewood chromosomes was characterized according to arm length (in micrometers) and classified as pairs of homologues (Table 1). This species contains relatively small submetacentric chromosomes (2n = 24) with lengths varying from 1.34 to 2.25 mm. The criteria for chromosome classification (Guerra, 1986) was used in this analysis and all chromo-somes were classified according to the decreasing size criteria (1 to 12). The nucleolar organizing region (NOR) was identified by the presence of a secondary constriction in the short arm of chromosome 7 (Figure 2). No differences in karyotype were observed between the two populations.
The presence of a nucleolus attached to the condensed chromosomes (Figure 2) is not uncommon after herbicide treatment in slide preparations, similar results having also been observed in Capsicum sp and Bixa orellana (data not shown).
The 2C value of rosewood showed a nuclear DNA content of 2.36 pg using DAPI or 2.32 pg using PI as fluorochromes to stain the nuclei suspension. Although these nuclear DNA contents were similar, the 2C value of 2.32 pg is more representative because PI staining has no bias for AT or GC-rich sequences within genomes (Dolezel et al., 1998; Shapiro, 2003)
The A. rosaeodora haploid group corresponds to the basic number of chromosomes (x = 12) characteristic of most Lauraceae species, as verified by Goldblatt and Johnson (2000) in nine other genera of this family. Although the characteristic chromosome number is conserved, the nuclear DNA content varies considerably among the members of the Lauraceae and the results are within the previously reported range.
Collectively these data describe the basic characteristics of the genome organization of A. rosaeodora with the quantification of the nuclear DNA content and the number and morphology of the chromosomes.
Acknowledgments
The authors thank Ms. Reginaldo A.F. Buzelli (Purdue University, USA) and Dr. Charles R. Clement (INPA, Brazil) for helpful discussions and critical reading of the manuscript, and Dr. Paulo T.S. Barbosa (INPA, Brazil) for plant material.
References
Arumuganathan K and Earle ED (1991) Nuclear DNA content of some important plant species. Plant Mol Biol Reporter 9:208-218.
Bawa KS and Seidler R (1998) Natural forest management and conservation of biodiversity in tropical forests. Conservation Biol 12:46-55.
Bennett MD and Leitch IJ (2003) Plant DNA C-values database, Royal Botanic Gardens http://www.rbgkew.org.uk/cval/homepage.html.
Bennett MD and Smith JB (1976) Nuclear DNA amounts in angiosperms. Philosophical Transactions of the Royal Society of London B 274:227-274.
Carr GD and McPherson G (1986) Chromosome numbers of New Caledonian plants. Anna Mo Bot Gard 73:486-489.
Carvalho CR and Saraiva LS (1997) High-resolution HKG-banding in maize mitotic chromosomes. J Plant Res 110:417-420.
Chatha GS and Bir SS (1987) Population analysis of some woody species from Palni Hills, south India. J Cytol Genet 22:83-94.
Chen R-Y (1993) Chromosome Atlas of Chinese Fruit Trees and Their Close Wild Relatives. Chromosome Atlas of Chinese Principal Economic Plants. International Academic Publishers, v. 1, 626 pp.
Dolezel J and Ghde W (1995) Sex determination in dioecious plants Melandrium album and M. rubrum using high-resolution flow cytometry. Cytometry 19:103-105.
Dolezel J, Greilhuber J, Lucretti S, Meister A, Lysak M, Nardi L and Obermayer R (1998) Plant genome size estimation by flow cytometry: Inter-laboratory comparison. Annals of Botany 82(sup A):17-26.
Ghelardini C, Galeotti N, Salvatore G and Mazzanti G (1999) Local anaesthetic activity of the essential oil of Lavandula angustifolia. Planta Med 65:700-703.
Goldblatt P and Johnson DE (2000) Index to Plant Chromosome Numbers 1996-1997. Monographs in Systematic Botany from the Missouri Botanical Garden 81:i-xi, 1-188.
Guerra MS (1986) Reviewing the chromosome nomenclature of Levan et al. Rev Bras Genet 9:741-743.
Huang S-F Z-F, Zhao Z-Y, Chen and Huang X-X (1989) Chromosome counts on one hundred species and infraspecific taxa. Acta Bot Sin 5:161-176.
Huang SY, Wang Z, Chen and Shi X (1988) Plant chromosome counts (4). Subtrop Forest Sci & Technol 16:25-30.
Inouye S, Takizawa T and Yamaguchi H (2001) Antibacterial activity of essential oils and their major constituents against respiratory tract pathogens by gaseous contact. J Antimicrob Chemoth 47:565-573.
Rasband W (1997) Image SXM 1.61. A public domain software for image analysis, written at the US National Institute of Health, extensions by Steve Barrett and available from the Internet by anonymous ftp from zippy.nimh.nih.gov.
Ribeiro JELS, Hopkins MJG, Vicentini A, Sothers CA, Costa MAS, Brito JM, Souza MAD, Lohrman LG, Assuno PACL, Silva CF, Mesquita M and Rocopio LC (1999) Flora da Reserva Ducke. Guia de Identificao das Plantas Vasculares de uma Floresta de Terra Firme na Amaznia Central. INPA/DFIP, Manaus, AM, 816 pp.
Rosa LS, Sa TDA, Ohashi ST, Barros PLC and Silva AJV (1997) Crescimento e sobrevivência de mudas de pau-rosa (Aniba rosaeodora Ducke) oriundas de três procedências, em funo de diferentes niveis de sombreamento, em condies de viveiro. Boletim da Faculdade de Ciências Agrarias do Para 28:37-62.
Rosa MSS, Mendona-Filho RR, Bizzo HR, Rodrigues IA, Soares RMA, Souto-Padron T, Alviano CS and Lopes AHCS (2003) Antileishmanial activity of a linalool-rich essential oil from Croton cajucara. Antimicrob Agents Ch 47:1895-1901.
Shapiro HM (2003) Practical Flow Cytometry. John Wiley & Sons, Inc., New York, 681 pp.
Sandhu PS and Mann SK (1988) SOCGI plant chromosome number reports VIII. J Cytol Genet 24:179-183.
Todua BT (1987) Karyology of laurel species and forms. Dokl Akad Nauk S.S.S.R, Ser Biol 3:445-452.
Vainstein A, Lewinsohn E, Pichersky E and Weiss D (2001) Floral fragrance. New inroads into an old commodity. Plant Physiol 127:1383-1389.
Wu Z-M (1995) Cytological studies on some plants of woody flora in Huangshan, Anhui Province. J Wuhan Bot Res 13:107-112.(Luis Antnio Serro Contim;)
IIUniversidade Federal de Viosa, Departamento de Biologia Geral, Viosa, MG, Brazil
IIIInstituto Nacional de Pesquisas da Amaznia, Departamento de Silvicultura Tropical, Manaus, AM, Brazil
ABSTRACT
Rosewood (Aniba rosaeodora Ducke, Lauraceae) is ecologically and economically important to the Amazon region. As a consequence of its economic importance, rosewood populations have been decimated in the Amazon forest. Species of nine genera of the Lauraceae family have characterized karyotypes with n = x = 12 chromosomes in the gametophytic phase but the genus Aniba is one of the least studied Lauraceae genera with a previously undescribed genome. We used cytogenetic techniques to determine that the A. rosaeodora karyotype contained 12 pairs (2n = 24) of relatively small submetacentric chromosomes with lengths ranging from 1.34 to 2.25 mm and a nucleolar organizer region (NOR) in the short arm of chromosome 7. Flow cytometry gave 2C = 2.32 pg of DNA, equivalent to approximately 2.24 x 109 base pairs.
Key words: rosewood, Aniba rosaeodora, Lauraceae, karyotype, flow cytometry.
Introduction
The Amazon forest is mega-biodiverse but its ecosystems are still poorly known (Bawa and Seidler, 1998). Rosewood (Aniba rosaeodora Ducke, Lauraceae) is an Amazonian tree that produces an essential oil which is in great demand both in Brazil and internationally. Rosewood oil contains large amounts of linalool, a compound widely used by the cosmetics industry (Vainstein et al., 2001) but which may also have therapeutic properties as an anesthetic (Ghelardini et al., 1999) and an antimicrobial agent (Rosa et al., 2003; Inouye et al., 2001) that may lead to the development of new products. Due to commercial demand, rosewood populations have decimated in its center of origin in the Amazon forest but a small number of individual trees continue to exist in the Brazilian states of Amazonas and Para (Rosa et al., 1997).
The Lauraceae family contains 52 genera and about 2500 described species (Ribeiro et al., 1999) distributed in the tropics and subtropics, the greatest concentration of species being in the Neotropics and Southeast Asia. The chromosome number has been quantified for many species of the nine Lauraceae genera, mostly from the northern hemisphere. The characteristic gametophytic chromosome number is n = 12 but some polyploids also occur (Goldblatt and Johnson, 2000). The genera Adenodaphne (Carr and McPherson, 1986), Lindera (Wu, 1995), Machilus (Sandhu and Mann, 1988), Neolitsea (Chatha and Bir, 1987), Persea (Chen, 1993), Phoebe (Sandhu and Mann, 1988) and Sassafras (Huang et al., 1989) all possess n = 12 but the genus Litsea (Huang et al., 1988) contains five species with n = 12 and one (L. glutinous) with n = 24, while the genus Lauros has species with 2n = 12 times X, where X varies from 3 to 6 (Todua, 1987).
The only Lauraceae species to have had its nuclear DNA content quantified by flow cytometry is Persea americana, which has 2C = 1.86 pg (Arumuganathan and Earle, 1991), although Bennett and Leitch (2003) used other methods to establish that Persea indica is 2C = 3.30 and Cinnamomum camphora C = 1.80.
The genus Aniba is one of the least known members of the Lauraceae family and in spite of the great scientific, ecological and economic importance of Aniba rosaeodora its genome size, genetic structure and chromosome number and morphology have not yet been characterized. In the work described in this paper we quantified the amount of nuclear DNA in A. rosaeodora and characterized its karyotype
Material and Methods
Plant material
Amazonian rosewood (Aniba rosaeodora Ducke, Lauraceae) seeds were collected from two wild populations in reserves in the Brazilian state of Amazonas, one being the Reserva Florestal Adolpho Ducke belonging to the Brazilian National Institute for Amazonian Research (Instituto Nacional de Pesquisas da Amaznia (INPA) Manaus, Amazonas, Brazil) and the other the Silves Reserve (Associao Vida Verde (AVIVE) da Amaznia, Silves, Amazonas, Brazil). The seeds were placed in germination chambers for 15 days at 30 °C and cultivated in the INPA forest seedling greenhouse in Manaus (3°8 S, 59°52 W).
Flow Cytometry
The method used was described by Dolezel and Ghde (1995), with minor modifications. Young and vigorous seedling leaves were washed, placed in recipients containing distilled water and maintained at 4 °C. Leaf fragments (2 cm2) were macerated in 1 mL of Otto-I lysis buffer (0.1 M citric acid monohydrate plus 0.5% (v/v) Tween 20) and the suspension filtered through 40 mm pore-size membranes and transferred to clean tubes which were centrifuged at 250 g. After centrifugation the pellet containing nuclei was collected and homogenized in 100 mL of Otto-I buffer which was separated in two aliquots, one being stained with 15 mM 4’,6’-Diamidino-2-phenylindole (DAPI) solution in Otto-II buffer (0.4 mM Na2HPO4.12H2O) for 15 min in the dark and the other with 75 mM propidium iodide (PI) plus 50 mg/mL Rnase in Otto-II buffer for 30 min. The analysis of the nuclei suspension was performed using a Partec PAS II/III Flow Cytometer (Partec Gmbh, Munster, Germany). For analysis of DAPI stained nuclei we used a high pressure mercury lamp (HBO-100 W) with KG 1, BG 38 and GG 435 filters while for propidium iodide stained nuclei we used a 480 nm argon ion laser (20 mW) with TK 560 and RG 610 filters. For internal controls we used Raphanus sativus cv Saxa (2C = 1.11 pg) kindly provided by Dr Jaroslav Dolezel (Institute of Experimental Botany, Tchec Republic). Three young leaves from each of three plants and approximately 10 thousand nuclei per plant sample were analyzed using the FlowMax Partec software. Samples with coefficients of variation above 3% were not used in these analyses. The results presented in pg were transformed into base pairs as described by Bennett and Smith (1976).
Cytogenetic preparations
Thirty roots of rosewood seedlings were treated with 5 mM Oryzalin solution for 3 h at 30 °C, washed in distilled water for 15 min and fixed in 3:1 methanol:acetic acid at -20 °C. After 24 h the roots were washed and macerated in 1:10 Flaxzym:distilled water at 35 °C for 90 min. The root tips were washed in distilled water for 20 min, fixed (3x) in 3:1 methanol:acetic acid and stored at -20 °C. The cytogenetic preparations were proceeded by cellular dissociation of the apical meristem (Carvalho and Saraiva, 1997) and then left to dry at room temperature before staining with 5% Giemsa solution in phosphate buffer (pH 6.8) for 5 min, washing twice in distilled water and drying at 50 °C.
Image analysis
Twenty images of good quality metaphases per root meristem were captured using a charge-coupled device (CCD) video-camera connected to an OlympusTM BX60 microscope equipped with a 100x immersion lens. Morphological analyses of the chromosomes were performed using the Image SXM software (Rasband, 1997) running on a MacintoshTM G4 computer. The arms of each chromosome were measured in pixel units and converted to a micrometer scale. The centromeric index was determined according to the criteria for morphologic classification of chromosomes (Guerra, 1986).
Results and Discussion
Flow cytometry
The flow cytometry analysis of the nuclei suspension generated histograms with peaks corresponding to the average of the G1/G0 nuclei DNA content. The R. sativus cv Saxa peak was calibrated to channel 100 (internal standard with 2C = 1.11 pg DNA). The results from the three A. rosaeodora DAPI stained nuclei samples showed G1/G0 peaks in channels 212, 213 and 214, corresponding to a mean value of 2C = 2.36 pg DNA (Figure 1a). The equivalent samples stained with PI generated G1/G0 A. rosaeodora nuclei peaks in channels 207, 209 and 211, corresponding to a mean value of 2C = 2.32 pg DNA (Figure 1b). The two populations of rosewood showed overlaying peaks, that is, no differences in DNA content. The second DNA content measurement (2C = 2.32 pg) was calculated to be equivalent to 2.24 x 109 base pairs.
Cytogenetics
Chromosome preparations and image analysis allowed us to obtain metaphases with appropriate cytogenetic quality. After incubation in a solution (5 mM) of the herbicide Oryzalin for 3 h at 30 °C, the morphology of the chromosomes showed standard C-metaphase condensation, although in some cells the nucleolus remained attached to the secondary constriction (Figure 2). These data were used for morphologic characterization and karyogram assembly (Figure 3). The morphology of the rosewood chromosomes was characterized according to arm length (in micrometers) and classified as pairs of homologues (Table 1). This species contains relatively small submetacentric chromosomes (2n = 24) with lengths varying from 1.34 to 2.25 mm. The criteria for chromosome classification (Guerra, 1986) was used in this analysis and all chromo-somes were classified according to the decreasing size criteria (1 to 12). The nucleolar organizing region (NOR) was identified by the presence of a secondary constriction in the short arm of chromosome 7 (Figure 2). No differences in karyotype were observed between the two populations.
The presence of a nucleolus attached to the condensed chromosomes (Figure 2) is not uncommon after herbicide treatment in slide preparations, similar results having also been observed in Capsicum sp and Bixa orellana (data not shown).
The 2C value of rosewood showed a nuclear DNA content of 2.36 pg using DAPI or 2.32 pg using PI as fluorochromes to stain the nuclei suspension. Although these nuclear DNA contents were similar, the 2C value of 2.32 pg is more representative because PI staining has no bias for AT or GC-rich sequences within genomes (Dolezel et al., 1998; Shapiro, 2003)
The A. rosaeodora haploid group corresponds to the basic number of chromosomes (x = 12) characteristic of most Lauraceae species, as verified by Goldblatt and Johnson (2000) in nine other genera of this family. Although the characteristic chromosome number is conserved, the nuclear DNA content varies considerably among the members of the Lauraceae and the results are within the previously reported range.
Collectively these data describe the basic characteristics of the genome organization of A. rosaeodora with the quantification of the nuclear DNA content and the number and morphology of the chromosomes.
Acknowledgments
The authors thank Ms. Reginaldo A.F. Buzelli (Purdue University, USA) and Dr. Charles R. Clement (INPA, Brazil) for helpful discussions and critical reading of the manuscript, and Dr. Paulo T.S. Barbosa (INPA, Brazil) for plant material.
References
Arumuganathan K and Earle ED (1991) Nuclear DNA content of some important plant species. Plant Mol Biol Reporter 9:208-218.
Bawa KS and Seidler R (1998) Natural forest management and conservation of biodiversity in tropical forests. Conservation Biol 12:46-55.
Bennett MD and Leitch IJ (2003) Plant DNA C-values database, Royal Botanic Gardens http://www.rbgkew.org.uk/cval/homepage.html.
Bennett MD and Smith JB (1976) Nuclear DNA amounts in angiosperms. Philosophical Transactions of the Royal Society of London B 274:227-274.
Carr GD and McPherson G (1986) Chromosome numbers of New Caledonian plants. Anna Mo Bot Gard 73:486-489.
Carvalho CR and Saraiva LS (1997) High-resolution HKG-banding in maize mitotic chromosomes. J Plant Res 110:417-420.
Chatha GS and Bir SS (1987) Population analysis of some woody species from Palni Hills, south India. J Cytol Genet 22:83-94.
Chen R-Y (1993) Chromosome Atlas of Chinese Fruit Trees and Their Close Wild Relatives. Chromosome Atlas of Chinese Principal Economic Plants. International Academic Publishers, v. 1, 626 pp.
Dolezel J and Ghde W (1995) Sex determination in dioecious plants Melandrium album and M. rubrum using high-resolution flow cytometry. Cytometry 19:103-105.
Dolezel J, Greilhuber J, Lucretti S, Meister A, Lysak M, Nardi L and Obermayer R (1998) Plant genome size estimation by flow cytometry: Inter-laboratory comparison. Annals of Botany 82(sup A):17-26.
Ghelardini C, Galeotti N, Salvatore G and Mazzanti G (1999) Local anaesthetic activity of the essential oil of Lavandula angustifolia. Planta Med 65:700-703.
Goldblatt P and Johnson DE (2000) Index to Plant Chromosome Numbers 1996-1997. Monographs in Systematic Botany from the Missouri Botanical Garden 81:i-xi, 1-188.
Guerra MS (1986) Reviewing the chromosome nomenclature of Levan et al. Rev Bras Genet 9:741-743.
Huang S-F Z-F, Zhao Z-Y, Chen and Huang X-X (1989) Chromosome counts on one hundred species and infraspecific taxa. Acta Bot Sin 5:161-176.
Huang SY, Wang Z, Chen and Shi X (1988) Plant chromosome counts (4). Subtrop Forest Sci & Technol 16:25-30.
Inouye S, Takizawa T and Yamaguchi H (2001) Antibacterial activity of essential oils and their major constituents against respiratory tract pathogens by gaseous contact. J Antimicrob Chemoth 47:565-573.
Rasband W (1997) Image SXM 1.61. A public domain software for image analysis, written at the US National Institute of Health, extensions by Steve Barrett and available from the Internet by anonymous ftp from zippy.nimh.nih.gov.
Ribeiro JELS, Hopkins MJG, Vicentini A, Sothers CA, Costa MAS, Brito JM, Souza MAD, Lohrman LG, Assuno PACL, Silva CF, Mesquita M and Rocopio LC (1999) Flora da Reserva Ducke. Guia de Identificao das Plantas Vasculares de uma Floresta de Terra Firme na Amaznia Central. INPA/DFIP, Manaus, AM, 816 pp.
Rosa LS, Sa TDA, Ohashi ST, Barros PLC and Silva AJV (1997) Crescimento e sobrevivência de mudas de pau-rosa (Aniba rosaeodora Ducke) oriundas de três procedências, em funo de diferentes niveis de sombreamento, em condies de viveiro. Boletim da Faculdade de Ciências Agrarias do Para 28:37-62.
Rosa MSS, Mendona-Filho RR, Bizzo HR, Rodrigues IA, Soares RMA, Souto-Padron T, Alviano CS and Lopes AHCS (2003) Antileishmanial activity of a linalool-rich essential oil from Croton cajucara. Antimicrob Agents Ch 47:1895-1901.
Shapiro HM (2003) Practical Flow Cytometry. John Wiley & Sons, Inc., New York, 681 pp.
Sandhu PS and Mann SK (1988) SOCGI plant chromosome number reports VIII. J Cytol Genet 24:179-183.
Todua BT (1987) Karyology of laurel species and forms. Dokl Akad Nauk S.S.S.R, Ser Biol 3:445-452.
Vainstein A, Lewinsohn E, Pichersky E and Weiss D (2001) Floral fragrance. New inroads into an old commodity. Plant Physiol 127:1383-1389.
Wu Z-M (1995) Cytological studies on some plants of woody flora in Huangshan, Anhui Province. J Wuhan Bot Res 13:107-112.(Luis Antnio Serro Contim;)