Does the functional leaf anatomy of <i>Justicia calycina</i> (Acanthaceae) reflect variation across a canopy gradient in the Southern Brazilian Amazon?

Lauton, Maísa Barbosa; Gressler, Eliana; Oliveira, Jaqueline Amorim de; Simioni, Priscila Fernanda; Gomes Ribeiro-Júnior, Norberto; Yamashita, Oscar Mitsuo; Silva, Ivone Vieira da

doi:10.1590/1677-941X-ABB-2021-0335

ABSTRACT

Justicia calycina is a subshrub well distributed in northern South America. Despite its widespread occurrence, little is known about its anatomy and plasticity in different environments. Our study aimed to evaluate how leaf anatomical traits of J. calycina adjust in forest areas with variations in canopy openness in the Southern Amazon, Mato Grosso State, Brazil. Forest areas were: Open and Dense Ombrophilous Forest, and Seasonal Deciduous Forest (rocky outcrop). We performed anatomical measurements in leaves sampled on 10 individuals in each forest site, with the help of usual anatomy techniques. Foliar anatomy of J. calycina showed similar pattern among the studied forests, with significant difference (p<0.05) in four leaf traits among 22 studied: vascular bundle diameter, palisade parenchyma thickness, stomatal density and trichome density in adaxial epidermis. These leaf traits showed high plasticity index, with higher values in Dense Forest and in Deciduous Forest. Even though J. calycina showed overall little anatomical variation among forest types, the few attributes that differed are fundamental in the photosynthesis process. The adjustment in leaf anatomical traits under different luminosity conditions demonstrates a degree of phenotypic plasticity in the species, which contributes to its distribution in different forest phytophysiognomies in Brazilian Amazonia.

Keywords:
Justicieae; structural attributes; phenotypic plasticity; sun leaves; tropical forest

Introduction

Tropical plant communities show variable environmental conditions, especially in microclimatic and edaphic factors. The coexistence and development of plant species is directly related to the potential that they have to adjust phenotypic characteristics in response to environmental variations (Pireda et al. 2019Pireda S, Silva OD, Borges NL et al. 2019. Acclimatization capacity of leaf traits of species co-occurring in restinga and seasonal semideciduous forest ecosystems. Environmental and Experimental Botany 164: 190-202.). The ability of plants to alter their phenotype in different environments is defined as phenotypic plasticity (Sultan 2000Sultan SE. 2000. Phenotypic plasticity for plant development, function and life history. Trends in Plant Science 5: 537-542.).

Leaf traits are among the most plastic in plants in response to environmental variations (Sultan 2000Sultan SE. 2000. Phenotypic plasticity for plant development, function and life history. Trends in Plant Science 5: 537-542.; Gratani 2014Gratani L. 2014. Plant phenotypic plasticity in response to environmental factors. Advances in Botany 2014: 208747.). Leaves are directly involved in photosynthetic processes and ecosystem processes (Garnier et al. 2001Garnier E, Laurent G, Bellmann A et al. 2001. Consistency of species ranking based on functional leaf traits. New Phytologist 152: 69-83.; Diaz et al. 2004Diaz S, Hodgson JG, Thompson K et al. 2004. The plant traits that drive ecosystems: evidence from three continents. Journal of Vegetation Science 15: 295-304.). Leaf morphological characteristics can significantly externalize the environmental stresses that plants are suffering or, conversely, show plasticity in response to anatomical adjustments (Garnier et al. 2001Garnier E, Laurent G, Bellmann A et al. 2001. Consistency of species ranking based on functional leaf traits. New Phytologist 152: 69-83.; Diaz et al. 2004Diaz S, Hodgson JG, Thompson K et al. 2004. The plant traits that drive ecosystems: evidence from three continents. Journal of Vegetation Science 15: 295-304.; Rosado & Mattos 2007Rosado BHP, Mattos EA. 2007. Variação temporal de características morfológicas de folhas em dez espécies do Parque Nacional da Restinga de Jurubatiba, Macaé, RJ, Brasil. Acta Botanica Brasilica 21: 741-752.). In this sense, plants that have greater phenotypic plasticity are more apt to coexist in different environments, allowing for a wide geographic distribution (Gratani 2014Gratani L. 2014. Plant phenotypic plasticity in response to environmental factors. Advances in Botany 2014: 208747.).

Variations on thickness of tissues (e.g., epidermis and mesophyll parenchyma) and density of stomata and trichome are usually found related to luminosity, water availability and soil fertility conditions (Dickison 2000Dickison WC. 2000. Integrative Plant Anatomy. San Diego, Academic Press.; Gratani 2014Gratani L. 2014. Plant phenotypic plasticity in response to environmental factors. Advances in Botany 2014: 208747.). These anatomical variations are associated with regulating light and CO₂ profiles within leaves and maximizing photosynthetic efficiencies (Dickison 2000Dickison WC. 2000. Integrative Plant Anatomy. San Diego, Academic Press.; Crang et al. 2018Crang R, Lyons-Sobaski S, Wise R. 2018. Plant anatomy: A concept-based approach to the structure of seed plants. Cham, Springer.). Sun leaves need to prevent high sunlight irradiance and/or water stress, and may have larger cells or more layers in palisade parenchyma making them more efficient in capturing and distributing of light through the mesophyll (e.g., Rabelo et al. 2013Rabelo GR, Vitória AP, da Silva MVA et al. 2013. Structural and ecophysiological adaptations to forest gaps. Trees 27: 259-272.; Gratani 2014Gratani L. 2014. Plant phenotypic plasticity in response to environmental factors. Advances in Botany 2014: 208747.; Campbell et al. 2018Campbell G, Mielke MS, Rabelo GR, Da Cunha M. 2018. Key anatomical attributes for occurrence of Psychotria schlechtendaliana (Müll. Arg.) Müll. Arg. (Rubiaceae) in different successional stages of a tropical moist forest. Flora 246: 33-41.). Sun leaves may also have more stomata per unit of leaf area, thicker epidermis and cuticle which favors greater light reflection, preventing leaf overheating (Rossatto et al. 2009Rossatto DR, Hoffmann WA, Franco CA. 2009. Stomatal traits of cerrado and gallery forest congeneric pairs growing in a transitional region in central Brazil. Acta Botanica Brasilica 23: 499-508.; Fang & Xiong 2015Fang Y, Xiong L. 2015. General mechanisms of drought response and their application in drought resistance improvement in plants. Cellular and Mollecular Life Science 72: 673-689.).

The Acanthaceae family has high diversity in Brazil (471 native species; Flora e Funga do Brasil 2020 2022Flora e Funga do Brasil 2020. 2022. Acanthaceae. Jardim Botânico do Rio de Janeiro, Rio de Janeiro. https://floradobrasil.jbrj.gov.br/FB33.
https://floradobrasil.jbrj.gov.br/FB33... ), but only few studies addressed leaf anatomical responses in different environmental conditions (e.g., Larcher & Boeger 2006Larcher L, Boeger MRT. 2006. Anatomia foliar de Odontonema strictum (Nees) O. Kuntze (Acanthaceae). Biotemas 19: 23-31.; Cassola et al. 2019Cassola F, da Silva MHR, Borghi AA et al. 2019. Morphoanatomical characteristics, chemical profiles, and antioxidant activity of three species of Justicia L. (Acanthaceae) under different growth conditions. Industrial Crops and Products 131: 257-265.). For Justicia calycina (= Justicia acuminatissima), some studies pointed to great morphological variability (Wasshausen & Wood 2004Wasshausen DC, Wood JRI. 2004. Acanthaceae of Bolivia. Contributions from the United States National Herbarium, 49: 1-152.; Wasshausen 2006Wasshausen D. 2006. A checklist of the Acanthaceae collected in the “Sira mountains” of Peru. Annalen des Naturhistorischen Museums in Wien. Serie B für Botanik und Zoologie 108B: 167-190.; Verdam et al. 2012Verdam MCS, Ohana DT, Araújo MGP, Guilhon-Simplicio F, Mendonça MS, Pereira MM. 2012. Morphology and anatomy of Justicia acuminatissima leaves. Revista Brasileira de Farmacognosia 22: 1212-1218.). This species is a perennial subshrub that occurs in several different phytophysiognomies and is well distributed in northern South America, including Brazil and a number of other countries (Tropicos 2022Tropicos. 2022. Tropicos.org. Saint Louis, Missouri Botanical Garden. http://www.tropicos.org.
http://www.tropicos.org... ). The species also has potential medicinal properties (e.g., Corrêa & Alcântara 2012Corrêa GM, Alcântara AFC. 2012. Chemical constituents and biological activities of species of Justicia: a review. Revista Brasileira de Farmacognosia 22: 220-238.; Cordeiro et al. 2019Cordeiro PM, Fernandes SM, Fonseca CD, Watanabe M, Lopes SM, Vattimo MFF. 2019. Effects of Justicia acuminatissima, or Amazonian Sara Tudo, on ischemic acute kidney injury: an experimental study. Revista da Escola de Enfermagem da USP 53: e03487.). Thus, it is important to deepen studies on the leaf morphoanatomy of J. calycina to understand its wide geographic distribution. Cassola et al. (2019)Cassola F, da Silva MHR, Borghi AA et al. 2019. Morphoanatomical characteristics, chemical profiles, and antioxidant activity of three species of Justicia L. (Acanthaceae) under different growth conditions. Industrial Crops and Products 131: 257-265., for example, observed changes in leaf anatomy of three Justicia species under different growth conditions. Besides, anatomical studies associated with taxonomy, phylogeny and degree of plasticity are useful to evaluate environmental heterogeneity, contributing to the conservation and management plans of natural vegetation (e.g., Metcalfe & Chalk 1979Metcalfe CR, Chalk L. 1979. Anatomy of the dicotyledons: Systematic anatomy of the leaf and stem, with a brief history of the subject. Vol 1. 2nd. edn. Oxford, Oxford Claredon Press.; Gupta & Shukla 2012Gupta R, Shukla K. 2012. Plant anatomy in relation to taxonomy. In: Gupta R (ed.). Plant Taxonomy: past, present, and future. New Delhi, The Energy and Resources Institute. p. 211-229.; Gratani 2014Gratani L. 2014. Plant phenotypic plasticity in response to environmental factors. Advances in Botany 2014: 208747.; Sokoloff et al. 2021Sokoloff DD, Jura-Morawiec J, Zoric L, Fay MF. 2021. Plant anatomy: at the heart of modern botany. Botanical Journal of the Linnean Society 195: 249-253. ).

In this context, our study aimed to evaluate how leaf anatomical traits of J. calycina vary among three forest areas with canopy openness variation in the Southern Brazilian Amazon. Considering that the forests in this region have different types of vegetation and environmental conditions, we expect that anatomical traits will differ among areas (structural adjustments), enabling acclimation and adaptation of J. calycina. We also expect that in forest areas with higher luminosity intensity, J. calycina will show typical variations of sun plants in leaf anatomical traits, such as thicker tissues and increased stomata and trichome density. These anatomical traits are among those that most vary in relation to environmental conditions, especially in sun-shade comparisons (Dickison 2000Dickison WC. 2000. Integrative Plant Anatomy. San Diego, Academic Press.; Gratani 2014Gratani L. 2014. Plant phenotypic plasticity in response to environmental factors. Advances in Botany 2014: 208747.).

Material and methods

Studied areas

Our study with Justicia calycina (Nees) V.A.W.Graham (Fig. 1 A ) was developed in three sites with different forest types in Southern Amazon, Mato Grosso State, Brazil: Open and Dense Ombrophilous forest, and Seasonal Deciduous Forest (Fig. 1B). The species is abundant in the three areas.

The Dense Ombrophilous Forest (hereafter Dense Forest) was sampled at the Reserva Surucuá, a particular reserve with about 50 hectares in the urban area of Alta Floresta municipality. In the studied forest portion (9°52’42”S, 56°05’55”W, 290 m altitude; Fig. 1 C ), the degree of anthropogenic disturbance is relatively low, the forest canopy reaches 20-30 m in height and the understory is dense and rich in shrub species (E. Gressler, personal communication).

The Open Ombrophilous Forest (hereafter Open Forest) was sampled in the Parque Ecológico Municipal C/E (9°52’39”S, 56°05’29”W, 280 m altitude), a public reserve located about 1 km from the Reserva Surucuá, comprising an area of 9.19 hectares (Fig. 1 C ), and average canopy height of 15-20 m (Colpini et al. 2009Colpini C, Travagin DP, Soares TS, Moraes SVS. 2009. Determination of bark percentage and volume of individual trees in an Open Ombrophylous Forest in northwest Mato Grosso. Acta Amazonica 39: 97-104.). The forest fragment suffered intense anthropic influence, showing many clearings and exotic plants (Varella et al. 2018Varella TL, Rossi AAB, Souza MDA et al. 2018. Estrutura populacional e distribuição espacial de Theobroma speciosum Willd. ex Spreng no norte do estado de Mato Grosso. Ciência Florestal 28: 115-126.).

The Seasonal Deciduous Forest (hereafter Deciduous Forest) was sampled in the Reserva Particular do Patrimônio Natural Mirante da Serra reserve (1616.7 ha) located in the municipality of Novo Mundo, about 40 km away from the other two studied forests. We sampled Justicia calycina at two points in a rocky outcrop with transitional area of Deciduous Forest and Dense Forest (9°34’59”S, 55°55’09”W, 290 m altitude, and 9°35’06”S, 55°55’05”W, 325 m altitude) with little/no anthropic disturbance (Fig. 1 D ). At these points the forest canopy is relatively open (20-25 m high) and most species are deciduous, losing their leaves in the dry season (Sasaki et al. 2010Sasaki D, Zappi DC, Milliken W, Henicka GS, Piva JH. 2010. Vegetação e plantas do Cristalino - um manual. Alta Floresta, Fundação Ecológica Cristalino - Royal Botanic Gardens - Kew.).

Figure 1
Individual aspect of Justicia calycina (Acanthaceae) (A) and studied areas in Southern Amazon, Mato Grosso State, Brazil (B-G). Reserva Surucuá (Dense Forest) (C, E). Parque Ecológico Municipal C/E (Open Forest) (C, F). RPPN Mirante da Serra (Deciduous Forest) (D, G). Arrows indicate J. calycina individuals in each forest site.

Rainy seasons in the region of Alta Floresta and Novo Mundo occur between October and April, and dry seasons between May and September (Caioni et al. 2014Caioni C, Caioni S, Silva ACS, Parente TL, Araújo OS. 2014. Análise da distribuição pluviométrica e de ocorrência do fenômeno climático ENOS no município de Alta Floresta - MT. Enciclopédia Biosfera 10: 2656-2666.). Open and Dense Forest are under the same meteorological conditions. In these areas, in 2016, total annual rainfall was 1911 mm, mean annual temperature 27.5 °C and mean annual air humidity 75.0 %. For the same year, in the Deciduous Forest, total annual rainfall was 2566 mm, mean annual temperature 27.2 °C and mean annual air humidity 85.6 % (^{Fig. S1} Figure S1 - Meteorological data sampled in 2016 in the forest sites where we studied leaf anatomy of Justicia calycina, in the Southern Brazilian Amazon. Minimum temperature (Tmin), mean temperature (Tmean) and maximum temperature (Tmax) (A-B). Rainfall and air relative humidity (C-D). The rainy season (October to April) is represented by the boxes in the respective months. ). Those data were collected in two meteorological stations, one installed in the Dense Forest and one installed about 3 km of distance from the Deciduous Forest (V Dubreuil, unpubl. data). There is no meteorological data available for 2017 in the Deciduous Forest, due to local equipment failure.

We measured luminosity conditions in each studied forest using hemispheric photographs taken with a digital professional camera (Nikon DSLR D600), equipped with a fisheye 8 mm lens (Sigma EX DG 1:3.5) and mounted on a tripod at 1.0 m aboveground. Photographs were taken on 27-28th September/2016, from 07:00 to 11:00 a.m., in points close to the sampled individuals in Dense Forest (9 points), Open Forest (3) and Deciduous Forest (4). We analyzed canopy openness (%) in the photographs using the program Gap Light Analyzer version 2.0 (Frazer et al. 1999Frazer GW, Canham CD, Lertzman KP. 1999. Gap Light Analyzer (GLA) version 2.0 - user manual and program documentation. Burnaby; Simon Fraser University; Millbrook British Columbia and the Institute of Ecosystem Studies.). Hemispheric fisheye photographs are widely used in ecological studies to estimate light conditions in forest understory (e.g., Dahlgren et al. 2007Dahlgren JP, von Zeipel H, Ehrlén J. 2007. Variation in vegetative and flowering phenology in a forest herb caused by environmental heterogeneity. American Journal of Botany 94: 1570-1576.). In the case of J. calycina, we took photographs when the equipment was available in our institution, which coincided with the beginning of the growing season (Lauton et al., unpubl. resLauton MB, Gressler E, Oliveira JA, Silva IV. Phenology of two species of Justicia (Acanthaceae) in Southern Brazilian Amazon. unpubl. res..) and may represent the general luminosity conditions under which the leaves collected in April/2017 for anatomy developed.

Anatomical measurements

In April/2017 (end of the rainy season), we randomly sampled four adult leaves (fully expanded and developed) from the middle plant part (between the first, second and third knots) of 10 adult individuals of Justicia calycina in each studied forest, to minimize influence of developmental stage on the analysis. We also collected fertile material (Fig. 1A), which we deposited at the Southern Amazon Herbarium (HERBAM). Vouchers: M.B. Lauton 01 (26587 - 25/IV/2017), M.B. Lauton 02 (26588 - 27/IV/2017) and M.B. Lauton 03 (26589 - 28/IV/2017). We fixed the leaves with FAA₅₀ (formaldehyde, glacial acetic acid and 50 % ethanol, with proportion of 5:5:90, respectively) for 48 hours, and later we preserved in 70 % ethanol according to the modified method of Johansen (1940Johansen DA. 1940. Plant microtechnique. New York, MacGraw-Hill.).

From each individual we analyzed two leaves, totaling 60 samples, without visually signals of senescence or damage caused by herbivores or pathogens. We used the method of Roeser (1962Roeser KR. 1962. Die nadel der Schwarzkiefer-masenprodukt und Keinstwert der Natur. Microkosmos 61: 33-36.) to make freehand cross sections (with razor blades), in the median region of each leaf, obtaining thin sections which were stained with Astra blue and Basic Fuchsin. The median region was selected because it is an area with more uniform tissue distribution in the leaf lamina (Appezzato-da-Glória & Carmello-Guerreiro 2012Appezzato-da-Glória B, Carmello-Guerreiro SM. 2012. Anatomia vegetal. 3rd edn. Viçosa, Editora UFV.). For the analysis of the epidermis, we used the technique of printing both leaf surfaces with a drop of universal cyanoacrylate ester instant adhesive on histological slides, as described by Segatto et al. (2004Segatto FB, Bisognin DA, Benedetti M, Costa LC, Rampelotto MV, Nicoloso FT. 2004. Técnica para o estudo da anatomia da epiderme foliar de batata. Ciência Rural 34: 1597-1601.).

We photographed each histological slide using a digital image capture device, coupled to a Leica ICC50 photomicroscope, with the support of software LAZ EZ 1.7.0. For the comparison among forest sites, we measured 22 leaf anatomical traits (anatomical variables) using the Anati Quanti software (Aguiar et al. 2007Aguiar TV, Sant’anna-Santos BF, Azevedo AA, Ferreira RS. 2007. Anati quanti: software de análises quantitativas para estudos em anatomia vegetal. Planta Daninha 25: 649-659.; Tab. 1, ^{Fig. S2} Figure S2 - Leaf anatomical traits measured in Justicia calycina in Southern Brazilian Amazon. ).

Statistical analysis and plasticity index

We compared luminosity conditions (canopy openness) among the three forest sites using Kruskal-Wallis test in STATISTICA 8.0 software. Forest types differed significantly in luminosity (H = 11.76, p = 0. 0028) and Deciduous Forest showed higher values than the other two forest sites (Fig. 2).

All the statistical analyses with anatomical data were performed using R package version 4.0.3 (R Development Core Team 2020R Development Core Team. 2020. R version 4.0.3. R: A language and environment for statistical computing. R Foundation for Statistical Computing. https://www.R-project.org/.
https://www.R-project.org/... ). First, we tested the assumptions for normality and homoscedasticity using Shapiro and Levene tests. We tested the relationships among anatomical variables with Spearman's correlation (^{Tab. S1} Table S1 - Lauton MB, Gressler E, Oliveira JA, Simioni PF, Ribeiro-Júnior, Yamashita OM, Silva IV. Does the functional leaf anatomy of Justicia calycina (Acanthaceae) reflect variation across a canopy gradient in the Southern Brazilian Amazon? Matrix of Spearman correlations for the 22 leaf anatomical variables of Justicia calycina evaluated in three forest sites, Southern Brazilian Amazon. High correlation (≥ 0.70). ) and considered a strong correlation when the pairs of variables showed a value above 0.70 (Kendall 1938Kendall MGA. 1938. New measure of rank correlation. Biometrika 30: 81-93.). In such cases, we eliminated one of the variables from the subsequent analysis using the potential adaptive explanation of the variable as an elimination criterion. Thus, the variables midrib size (MIDS), spongy parenchyma thickness (SPT) and stomatal index (STI) were excluded (^{Tab. S1} Figure S2 - Leaf anatomical traits measured in Justicia calycina in Southern Brazilian Amazon. ).

We performed a PCA (Principal Components Analysis) with data of the three studied forests using the anatomical variables with the highest factorial load values for significant axes, selecting them for comparison among the forest types. To identify which anatomical variables contribute significantly to distinguish the studied forest sites, we performed the Kruskal-Wallis test. After that, we applied Dunn's multiple comparison test with Bonferroni's correction (PMCMR package; Pohlert 2014Pohlert T. 2014. The Pairwise Multiple Comparison of Mean Ranks Package (PMCMR). https://cran.r-project.org/web/packages/pmcmr/pmcmr.pdf
https://cran.r-project.org/web/packages/... ) on the variables with positive results in the previous tests.

For the variables which were significantly different among forest types we calculated the plasticity index (PI), which ranges from 0 (no plasticity) to 1 (maximum plasticity), with values higher than 0.6 interpreted as high plasticity (Valladares et al. 2000Valladares F, Wright SJ, Lasso E, Kitajima K, Pearcy RW. 2000. Plastic phenotypic response to light of 16 rainforest shrubs (Psychotria) differing in shade tolerance. Ecology 81: 1925-1936.; 2006Valladares F, Sanchez-Gomez D, Zavala MA. 2006. Quantitative estimation of phenotypic plasticity: bridging the gap between the evolutionary concept and its ecological applications. Journal of Ecology 94: 1103-1116.).

Figure 2
Comparison of canopy openness (%) among the three forests where we sampled leaves of Justicia calycina and respective hemispheric photographs examples. Kruskal-Wallis test revealed significant differences among forest sites (H = 11.76, p = 0.0028).

Results

Qualitative analysis

In the three studied forest sites, Justicia calycina showed hypostomatic leaves, midrib with a bicollateral vascular bundle in an open arc and 2-3 accessory bundles, one-layered adaxial and abaxial epidermis, dorsiventral mesophyll and both epidermal surfaces with trichome and cystoliths (Figs. 3, 4).

We observed only slight qualitative differences in cross and paradermal sections among the forest sites. The epidermal cells showed sinuous contour, with visually less sinuosity and thicker walls in Deciduous Forest (Fig. 3). Both the adaxial and abaxial epidermal surfaces presented cystoliths and numerous trichomes (or their scars) mainly on the abaxial surface (Fig. 3). In the midrib we observed little visual variation among forest types in relation to the size of vascular bundles (larger in Dense Forest) and a slight difference in the collenchyma position, which in the Open Forest was more dispersed than the other two forests (Fig. 4 A, C, E ).

In the leaf lamina, anatomical traits were visually similar among forest sites (Fig. 4 B, D, F ). Palisade parenchyma showed a single layer and spongy parenchyma showed four to five layers. The cuticle was relatively thin (less than 25 % of the adjacent epidermal cell size) and stomata occurred in the same level of other epidermal cells.

Figure 3
Paradermal sections of the leaf lamina of Justicia calycina in three forest types in Southern Brazilian Amazon: Dense Forest (A-B), Open Forest (C-D) and Deciduous Forest (E-F). Adaxial epidermis with cystoliths in detail (A, C, E). Abaxial epidermis with stomata positioning in detail (B, D, F). White arrows indicate trichome or scars and black arrows indicate cystoliths. Bars: 100 μm.

Figure 4
Cross-sections of the leaf midrib (A, C, E) and lamina (B, D, F) of Justicia calycina in three forest types in Southern Brazilian Amazon: Dense Forest (A-B), Open Forest (C-D) and Deciduous Forest (E-F). Abbreviations: P = phloem; X = xylem; SC = sclerenchyma; CO = collenchyma; SVB = secondary vascular bundle; TR = trichome; AD = abaxial epidermis; AB = abaxial epidermis; VB = vascular bundle; PP = palisade parenchyma; SP = spongy parenchyma; ST = stomata. Bars: 200 μm (A, C, E); 100 μm (B, D, F).

Quantitative analysis

The PCA showed an overlap of the three studied forest sites regarding anatomical variables, indicating a common anatomical pattern among the areas, with a greater distribution of sample range in the Deciduous Forest (Fig. 5). The studied forests differed significantly in four anatomical variables among the 22 analyzed (p < 0.001; Tab. 1).

In the midrib, the vascular bundle diameter (VBD) showed higher values in Dense Forest. In the leaf lamina (cross-section), the thickness of palisade parenchyma (PPT) was significantly higher in Deciduous Forest. In the paradermal section, the variables which differ significantly among forest types were stomatal density (STD) and trichome density in adaxial epidermis (TRIAD), both with higher values in Open and Deciduous Forest (Tab. 1).

Figure 5
Principal Component Analysis (PCA) with 18 leaf anatomical variables of Justicia calycina in three forest sites in Southern Brazilian Amazon (A) and contribution of each variable to the distribution of samples (B). Forest sites: Dense Forest, Open Forest and Deciduous Forest.

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Table 1
Means and standard deviations of 22 leaf anatomical traits measured in Justicia calycina in three forest sites, Southern Brazilian Amazon. VBS, SPT and STI were excluded from the analysis due to high correlation values with other leaf traits. *Significant differences among forest sites detected in Dunn's multiple comparison test (p < 0.001); different letters indicate statistical difference on the line. Ns: non-significant result. PI = plasticity index.

Discussion

Our results showed that leaf anatomical traits of Justicia calycina were overall similar among the three forest sites - Dense, Open and Deciduous Forest - studied in the Southern Brazilian Amazon. We found only few significant differences among forest sites, which may be related to variations in luminosity conditions. The leaf traits which differed among forests showed high plasticity, representing a certain degree of acclimation/adaptation of J. calycina according to Valladares et al. (2006Valladares F, Sanchez-Gomez D, Zavala MA. 2006. Quantitative estimation of phenotypic plasticity: bridging the gap between the evolutionary concept and its ecological applications. Journal of Ecology 94: 1103-1116.).

The thicker palisade parenchyma and higher stomatal and trichome density (PPT, STD and TRIAD, respectively) we verified in the leaves of Deciduous Forest may be interpreted as typical changes of sun plants (i.e., plants under higher luminosity conditions). This forest is located in a rocky outcrop and showed significant greater canopy openness due to the sparse distribution of woody plants (Silva et al. 2020Silva DR, Soares-Lopes CRA, Gressler E, Eisenlohr PV. 2020. Woody vegetation associated with rocky outcrops in Southern Amazonia: a starting point to unveil a unique flora. Biota Neotropica 20: e20190874.). Along with this, at the time of leaf sampling for anatomical measurements (rainy-dry transition season), woody plants of the Deciduous Forest start to shedding leaves (Sasaki et al. 2010Sasaki D, Zappi DC, Milliken W, Henicka GS, Piva JH. 2010. Vegetação e plantas do Cristalino - um manual. Alta Floresta, Fundação Ecológica Cristalino - Royal Botanic Gardens - Kew.; E. Gressler, personal communication), which contributes to making this forest even more illuminated in comparison to the other two studied forests (both evergreen). Sun leaves usually contain an increased number of palisade layers and greater palisade cell elongation (Lange et al. 1981Lange OL, Nobel PS, Osmond CB, Ziegler H. 1981. Physiological plant ecology I: Responses to the physical environment. Berlin, Springer.; Dickison 2000Dickison WC. 2000. Integrative Plant Anatomy. San Diego, Academic Press.; Gratani 2014Gratani L. 2014. Plant phenotypic plasticity in response to environmental factors. Advances in Botany 2014: 208747.). The elongation of palisade cells in sun leaves has been related to a reduction in mesophyll resistance to CO₂ and optimization of light absorption allowing light to channel deeper into lower leaf cell layers, such as the spongy cells where the light is scattered (Vogelmann & Martin 1993Vogelmann TC, Martin G. 1993. The functional significance of palisade tissue: penetration of directional vs. diffuse light. Plant, Cell & Environment 16: 65-72.; Théroux‐Rancourt & Gilbert 2017Théroux-Rancourt G, Gilbert ME. 2017. The light response of mesophyll conductance is controlled by structure across leaf profiles. Plant, Cell and Environment 40: 726-740.).

Regarding stomata, the higher density (STD) we observed in the Open and Deciduous Forests may also be explained by higher luminosity in these forests. Stomata of a given species can largely vary in quantity, distribution, size and shape in response to environmental factors (Willmer & Fricker 1996Willmer C, Fricker M. 1996. Stomata. 2nd. edn. Dordrecht, Springer.; Larcher 2003Larcher W. 2003. Physiological plant ecology. 4th. edn. New York, Springer.; Camargo & Marenco 2011Camargo MAB, Marenco RA. 2011. Density, size and distribution of stomata in 35 rainforest tree species in Central Amazonia. Acta Amazonica 41: 205-212.). Sun leaves usually present high stomatal frequency, being necessary to maximize CO₂ absorption rates, to water saving and to prevent excessive leaf heating under high irradiance (Givnish 1988Givnish TJ. 1988. Adaptation to sun and shade: a whole-plant perspective. Australian Journal of Plant Physiology 15: 63-92.; Bertolino et al. 2019Bertolino LT, Caine RS, Gray JE. 2019. Impact of stomatal density and morphology on water-use efficiency in a changing world. Frontiers in Plant Science 10: 225.; Lambers & Oliveira 2019Lambers H, Oliveira RS. 2019. Plant Water Relations. In: Lambers H, Oliveira RS (eds.). Plant Physiological Ecology. Cham, Springer . pp. 187-263.). The lower stomatal density in Dense Forest can be an indicator of larger leaves in this forest, because stomata are more spread out in these leaves (Franks & Farquhar 2007Franks PJ, Farquhar GD. 2007. The mechanical diversity of stomata and its significance in gas-exchange control. Plant Physiology 143: 78-87.).

The higher trichome density in adaxial epidermis (TRIAD) of J. calycina leaves from the Decidual Forest may be related to the protection of intense luminosity and desiccation, given the high light intensities of this forest. Highly pubescent surfaces can reflect sunlight and decrease transpiration rates, especially in the adaxial epidermis which is exposed directly to sun and therefore present higher temperature and transpiration than abaxial epidermis (Fahn & Cutler 1992Fahn A, Cutler DF. 1992. Xerophytes. Berlin, Gebrüder Borntraeger.; Roy et al. 1999Roy BA, Stanton ML, Eppley SM. 1999. Effects of environmental stress on leaf hair density and consequences for selection. Journal of Evolutionary Biology 12: 1089-1103.; Dickison 2000Dickison WC. 2000. Integrative Plant Anatomy. San Diego, Academic Press.; Larcher 2003Larcher W. 2003. Physiological plant ecology. 4th. edn. New York, Springer.; Ichie et al. 2016Ichie T, Inoue Y, Takahaski N, Kamiya K, Kenzo T. 2016. Ecological distribution of leaf stomata and trichomes among tree species in a Malaysian lowland tropical rain forest. Journal of Plant Research 129: 625-635.).

The epidermal cells of the adaxial surface of J. calycina showed thicker walls and slightly less sinuous outline in Deciduous Forest compared to the other forest sites. In environments with high luminosity intensity, such as the Deciduous Forest, epidermal cells usually have thicker walls and less or no sinuosity (Evert 2013Evert RF. 2013. Anatomia das plantas de Esau: Meristemas, células e tecidos do corpo da planta - sua estrutura, função e desenvolvimento. 3rd edn. São Paulo, Blucher.). According to Roth (1984Roth I. 1984. Stratification of tropical forests as seen in leaf structure. Tasks for vegetation science 6. Dordrecht, Kluwer Academic Publishers.), thicker walls increase the protective character of the epidermis.

The greater diameter of the central vascular bundle (VBD) in Dense Forest could indicate that in this forest, due to the significant lower luminosity, plants of J. calycina have larger leaves and therefore need to invest more in supporting tissues and major veins (e.g., Chazdon 1985Chazdon RL. 1985. Leaf display, canopy structure, and light interception of two understory palm species. American Journal of Botany 72: 1493-1502.; Niinemets & Sack 2006Niinemets Ü, Sack L. 2006. Structural determinants of leaf light-harvesting capacity and photosynthetic potentials. In: Esser K, Lüttge U, Beyschlag W, Murata J. (eds.). Progress in Botany (Genetics Physiology Systematics Ecology). Vol. 67. Berlin-Heidelberg, Springer. pp. 385-419.). Unfortunately, we did not measure the size and area of the collected leaves to confirm this hypothesis.

The few anatomical differences we detected among forests in J. calycina may be explained by the interaction of luminosity and other environmental variables such as temperature and humidity. Plants in rocky outcrops, as the studied Deciduous Forest, usually deal with stressful environmental conditions such as high insolation and temperature, desiccant winds, low humidity and poor and shallow soil (Prance 1996Prance GT. 1996. Islands in Amazonia. Philosophical Transactions of the Royal Society B 351: 823-833.; Porembski & Barthlott 2000Porembski S, Barthlott W. 2000. Inselbergs: Biotic diversity of isolated rock outcrops in tropical and temperate regions. Berlin-Heidelberg, Springer .). According to Porembski (2007)Porembski S. 2007. Tropical inselbergs: habitat types, adaptive strategies and diversity patterns. Revista Brasileira de Botânica 30: 579-586., rocky outcrops offer several microhabitats, such as crevices, depressions and soil islands, causing great microenvironmental variation. In the studied Deciduous Forest, the higher annual rainfall may contribute to maintaining a certain degree of humidity in the forest. Another explanation for the few anatomical differences among the studied forests is the intense herbivory observed in J. calycina leaves (MB Lauton et al., unpubl. res.), which may limit plant phenotypic plasticity (Valladares et al. 2007Valladares F, Gianoli E, Valladares JMG. 2007. Ecological limits to plant phenotypic plasticity. New Phytologist 176: 749-763.).

In the same region and similar forest types of our study, other studies have also found anatomical variations in understory species related to environmental conditions, though with overall low plasticity index (Ariano & Silva 2016Ariano APR, Silva IV. 2016. Leaf anatomy of Qualea parviflora (Vochysiaceae) in three phytophysiognomies of the Mato Grosso State, Brazil. Acta Amazonica 46: 119-126.; Dardengo et al. 2017Dardengo JFE, Rossi AAB, Silva IV, Pessoa MJG, Silva CJ. 2017. Análise da influência luminosa nos aspectos anatômicos de folhas de Theobroma speciosum Willd ex Spreng. (Malvaceae). Ciência Florestal 27: 843-851.; Rocha et al. 2019Rocha VAP, Pereira AA, Bento KBD, Fagundes OS, Ribeiro Junior NG, SILVA IV. 2019. Respostas anatômicas de Eumachia kappleri em três áreas da Amazônia Mato-Grossense. Revista Ibero-Americana de Ciências Ambientais 10: 74-82.; Müller et al. 2020Müller AO, Franco AA, Ribeiro Júnior NG, Gressler E, Rocha VLP, Silva IV. 2020. Estratégias adaptativas foliares de Miconia nervosa (Melastomataceae) na Amazônia Matogrossense. Rodriguésia 71: e01052018.). On the other hand, in savannas and cerrado phytophysiognomies in the Cerrado-Amazon transition of Mato Grosso State, some studies revealed phenotypic plasticity with high occurrence of xeromorphic anatomical traits in most species (Simioni et al. 2017Simioni PF, Eisenlohr PV, Pessoa MJG, da Silva IV. 2017. Elucidating adaptive strategies from leaf anatomy: do Amazonian savannas present xeromorphic characteristics? Flora 226: 38-46.; Pessoa et al. 2019Pessoa MJG, Guisoni JJ, Simioni PF, Pireda S, Xavier V, Silva IVD. 2019. Leaf structural traits of three species of Qualea Mart. (Vochysiaceae) in a cerradão area in the Cerrado-Amazonian Forest transition. Ciência Florestal 29: 1082-1089.). It is well known that leaf anatomical traits vary among species, according to their ability to acclimation and intensity of light received (e.g., Rozendaal et al. 2006Rozendaal DMA, Hurtado VH, Poorter L. 2006. Plasticity in leaf traits of 38 tropical tree species in response to light; relationships with light demand and adult stature. Functional Ecology 20: 207-216.; Markesteijn et al. 2007Markesteijn L, Poorter L, Bongers F. 2007. Light-dependent leaf trait variation in 43 tropical dry forest tree species. American Journal of Botany 94: 515-525.; Liu et al. 2019Liu C, Li Y, Xu L, Chen Z, He N. 2019. Variation in leaf morphological, stomatal, and anatomical traits and their relationships in temperate and subtropical forests. Scientific Reports 9: 5803.). The plasticity in anatomical responses that we found in J. calycina individuals under different luminosity conditions probably contributes to its wide distribution in different forest phytophysiognomies of the Amazon region.

To the best of our knowledge, this is the first study of the functional leaf anatomy of J. calycina comparing different forest phytophysiognomies in Brazil. Contrary to our expectations, forest sites with different canopy openness (or light intensity) showed only few significant differences in leaf anatomy of J. calycina. The differences we found were related to stomatal/trichome density and thickness of palisade parenchyma/vascular tissues, which are fundamental leaf traits in photosynthetic processes and in plant water transport. Our results can help to deepen physiological studies, directing to integrated studies of plant anatomy and physiology, seeking to elucidate the photosynthetic mechanism of this species and its strategies to deal with different environmental factors.

Acknowledgements

We thank Mato Grosso Research Foundation (FAPEMAT) for undergraduate fellowships received by MBL and JAO, and Coordination for the Improvement of Higher Education Personnel (CAPES/PNPD) for post-doctoral fellowship received by EG. We are grateful to all the partners from Laboratório de Anatomia Vegetal (LAAV-UNEMAT) for their help in field and laboratory works. We also thank the Cristalino Foundation for permission and logistical support in the studied areas.

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Supplementary material

The following online material is available for this article:

Table S1 - Lauton MB, Gressler E, Oliveira JA, Simioni PF, Ribeiro-Júnior, Yamashita OM, Silva IV. Does the functional leaf anatomy of Justicia calycina (Acanthaceae) reflect variation across a canopy gradient in the Southern Brazilian Amazon? Matrix of Spearman correlations for the 22 leaf anatomical variables of Justicia calycina evaluated in three forest sites, Southern Brazilian Amazon. High correlation (≥ 0.70).

Figure S1 - Meteorological data sampled in 2016 in the forest sites where we studied leaf anatomy of Justicia calycina, in the Southern Brazilian Amazon. Minimum temperature (Tmin), mean temperature (Tmean) and maximum temperature (Tmax) (A-B). Rainfall and air relative humidity (C-D). The rainy season (October to April) is represented by the boxes in the respective months.

Figure S2 - Leaf anatomical traits measured in Justicia calycina in Southern Brazilian Amazon.

Publication Dates

Publication in this collection
07 Nov 2022
Date of issue
2022

History

Received
08 Nov 2021
Accepted
24 Mar 2022

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Aguiar TV, Sant’anna-Santos BF, Azevedo AA, Ferreira RS. 2007. Anati quanti: software de análises quantitativas para estudos em anatomia vegetal. Planta Daninha 25: 649-659.

[2] Appezzato-da-Glória B, Carmello-Guerreiro SM. 2012. Anatomia vegetal. 3rd edn. Viçosa, Editora UFV.

[3] Ariano APR, Silva IV. 2016. Leaf anatomy of Qualea parviflora (Vochysiaceae) in three phytophysiognomies of the Mato Grosso State, Brazil. Acta Amazonica 46: 119-126.

[4] Bertolino LT, Caine RS, Gray JE. 2019. Impact of stomatal density and morphology on water-use efficiency in a changing world. Frontiers in Plant Science 10: 225.

[5] Caioni C, Caioni S, Silva ACS, Parente TL, Araújo OS. 2014. Análise da distribuição pluviométrica e de ocorrência do fenômeno climático ENOS no município de Alta Floresta - MT. Enciclopédia Biosfera 10: 2656-2666.

[6] Camargo MAB, Marenco RA. 2011. Density, size and distribution of stomata in 35 rainforest tree species in Central Amazonia. Acta Amazonica 41: 205-212.

[7] Campbell G, Mielke MS, Rabelo GR, Da Cunha M. 2018. Key anatomical attributes for occurrence of Psychotria schlechtendaliana (Müll. Arg.) Müll. Arg. (Rubiaceae) in different successional stages of a tropical moist forest. Flora 246: 33-41.

[8] Cassola F, da Silva MHR, Borghi AA et al 2019. Morphoanatomical characteristics, chemical profiles, and antioxidant activity of three species of Justicia L. (Acanthaceae) under different growth conditions. Industrial Crops and Products 131: 257-265.

[9] Chazdon RL. 1985. Leaf display, canopy structure, and light interception of two understory palm species. American Journal of Botany 72: 1493-1502.

[10] Colpini C, Travagin DP, Soares TS, Moraes SVS. 2009. Determination of bark percentage and volume of individual trees in an Open Ombrophylous Forest in northwest Mato Grosso. Acta Amazonica 39: 97-104.

[11] Cordeiro PM, Fernandes SM, Fonseca CD, Watanabe M, Lopes SM, Vattimo MFF. 2019. Effects of Justicia acuminatissima, or Amazonian Sara Tudo, on ischemic acute kidney injury: an experimental study. Revista da Escola de Enfermagem da USP 53: e03487.

[12] Corrêa GM, Alcântara AFC. 2012. Chemical constituents and biological activities of species of Justicia: a review. Revista Brasileira de Farmacognosia 22: 220-238.

[13] Crang R, Lyons-Sobaski S, Wise R. 2018. Plant anatomy: A concept-based approach to the structure of seed plants. Cham, Springer.

[14] Dahlgren JP, von Zeipel H, Ehrlén J. 2007. Variation in vegetative and flowering phenology in a forest herb caused by environmental heterogeneity. American Journal of Botany 94: 1570-1576.

[15] Dardengo JFE, Rossi AAB, Silva IV, Pessoa MJG, Silva CJ. 2017. Análise da influência luminosa nos aspectos anatômicos de folhas de Theobroma speciosum Willd ex Spreng. (Malvaceae). Ciência Florestal 27: 843-851.

[16] Diaz S, Hodgson JG, Thompson K et al 2004. The plant traits that drive ecosystems: evidence from three continents. Journal of Vegetation Science 15: 295-304.

[17] Dickison WC. 2000. Integrative Plant Anatomy. San Diego, Academic Press.

[18] Evert RF. 2013. Anatomia das plantas de Esau: Meristemas, células e tecidos do corpo da planta - sua estrutura, função e desenvolvimento. 3rd edn. São Paulo, Blucher.

[19] Fahn A, Cutler DF. 1992. Xerophytes. Berlin, Gebrüder Borntraeger.

[20] Fang Y, Xiong L. 2015. General mechanisms of drought response and their application in drought resistance improvement in plants. Cellular and Mollecular Life Science 72: 673-689.

[21] Flora e Funga do Brasil 2020. 2022. Acanthaceae. Jardim Botânico do Rio de Janeiro, Rio de Janeiro. https://floradobrasil.jbrj.gov.br/FB33
» https://floradobrasil.jbrj.gov.br/FB33

[22] Franks PJ, Farquhar GD. 2007. The mechanical diversity of stomata and its significance in gas-exchange control. Plant Physiology 143: 78-87.

[23] Frazer GW, Canham CD, Lertzman KP. 1999. Gap Light Analyzer (GLA) version 2.0 - user manual and program documentation. Burnaby; Simon Fraser University; Millbrook British Columbia and the Institute of Ecosystem Studies.

[24] Garnier E, Laurent G, Bellmann A et al 2001. Consistency of species ranking based on functional leaf traits. New Phytologist 152: 69-83.

[25] Givnish TJ. 1988. Adaptation to sun and shade: a whole-plant perspective. Australian Journal of Plant Physiology 15: 63-92.

[26] Gratani L. 2014. Plant phenotypic plasticity in response to environmental factors. Advances in Botany 2014: 208747.

[27] Gupta R, Shukla K. 2012. Plant anatomy in relation to taxonomy. In: Gupta R (ed.). Plant Taxonomy: past, present, and future. New Delhi, The Energy and Resources Institute. p. 211-229.

[28] Ichie T, Inoue Y, Takahaski N, Kamiya K, Kenzo T. 2016. Ecological distribution of leaf stomata and trichomes among tree species in a Malaysian lowland tropical rain forest. Journal of Plant Research 129: 625-635.

[29] Johansen DA. 1940. Plant microtechnique. New York, MacGraw-Hill.

[30] Kendall MGA. 1938. New measure of rank correlation. Biometrika 30: 81-93.

[31] Lambers H, Oliveira RS. 2019. Plant Water Relations. In: Lambers H, Oliveira RS (eds.). Plant Physiological Ecology. Cham, Springer . pp. 187-263.

[32] Lange OL, Nobel PS, Osmond CB, Ziegler H. 1981. Physiological plant ecology I: Responses to the physical environment. Berlin, Springer.

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Variables	Abbreviations	Dense Forest	Open Forest	Deciduous Forest	PI
Midrib size (μm)	MIDS ^excluded	1252.43 ± 166.19	1140.83 ± 167.59	1178.10 ± 254.44
Vascular bundle diameter (μm)	VBD *	616.33 ± 147.96^a	485.02 ± 105.99^b	515.19 ± 142.22^ab	0.63
Vascular bundle thickness (μm)	VBT ^ns	205.32 ± 32.30	200.32 ± 20.43	204.72 ± 41.51
Vascular bundle total size (μm)	VBTS ^ns	821.65 ± 157.21	685.34 ± 116.18	719.91 ± 173.20
Sclerenchyma thickness (μm)	SCL ^ns	29.48 ± 4.17	29.52 ± 5.57	29.19 ± 6.27
Collenchyma thickness adaxial epidermis (μm)	COLAD ^ns	86.04 ± 11.92	76.49 ± 10.54	84.71 ± 16.36
Collenchyma thickness abaxial epidermis (μm)	COLAB ^ns	61.17 ± 13.30	58.36 ± 12.78	60.66 ± 13.18
Cuticle thickness adaxial epidermis (μm)	CUTAD ^ns	4.64 ± 1.16	5.73 ± 1.74	5.44 ± 1.64
Cuticle thickness abaxial epidermis (μm)	CUTAB ^ns	3.29 ± 1.34	3.11 ± 1.20	3.91 ± 1.09
Adaxial epidermis thickness (μm)	ADEP ^ns	26.08 ± 6.43	24.28 ± 6.68	23.48 ± 4.77
Abaxial epidermis thickness (μm)	ABEP ^ns	19.40 ± 5.53	20.30 ± 4.01	17.42 ± 5.67
Palisade parenchyma thickness (μm)	PPT *	36.96 ± 6.40^b	37.05 ± 6.19^ab	42.30 ± 6.99^a	0.52
Spongy parenchyma thickness (μm)	SPT ^excluded	84.34 ± 14.36	82.26 ± 18.39	80.91 ± 22.18
Palisade to spongy parenchyma ratio (µm·µm ^-1)	PP_SP ^ns	0.45 ± 0.11	0.47 ± 0.13	0.55 ± 0.15
Secondary vascular bundle size (μm)	SVBS ^ns	61.80 ± 12.28	64.34 ± 21.42	64.14 ± 9.86
Lamina thickness (μm)	LAMT ^ns	167.88 ± 19.49	164.50 ± 19.64	169.32 ± 27.88
Stomatal index abaxial epidermis (%)	STI ^excluded	18.63 ± 2.80	22.95 ± 2.70	23.56 ± 4.69
Stomatal density abaxial epidermis (stomata per mm²)	STD *	135.24 ± 44.05^b	175.48 ± 49.51^a	171.82 ± 51.14^ab	0.65
Trichome density adaxial epidermis (trichome per mm²)	TRIAD *	9.42 ± 4.14^c	10.80 ± 6.87^ab	14.59 ± 4.10^a	0.78
Trichome density abaxial epidermis (trichome per mm²)	TRIAB ^ns	26.88 ± 7.57	32.28 ± 8.93	31.24 ± 9.44
Oblong cystoliths density adaxial epidermis (cystoliths per mm²)	CYSAD ^ns	2.53 ± 2.22	3.45 ± 2.17	4.36 ± 2.57
Oblong cystoliths density abaxial epidermis (cystoliths per mm²)	CYSAB ^ns	8.38 ± 3.36	8.27 ± 3.02	9.30 ± 3.37