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Scientia Agricola - Tiller size/population density compensation in grazed Coastcross bermudagrass swards

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Scientia Agricola

Print version ISSN 0103-9016

Sci. agric. vol.58 no.4 Piracicaba Oct./Dec. 2001

http://dx.doi.org/10.1590/S0103-90162001000400002 

TILLER SIZE/POPULATION DENSITY COMPENSATION IN GRAZED COASTCROSS BERMUDAGRASS SWARDS

 

André Fischer Sbrissia1,3; Sila Carneiro da Silva2*; Carlos Augusto Brandão de Carvalho1,3; Roberta Aparecida Carnevalli1,4; Luiz Felipe de Moura Pinto1,4; Jaílson Lara Fagundes1,4; Carlos Guilherme Silveira Pedreira2
1 Graduate Student in Animal Science and Pastures - USP/ESALQ.
2Depto. de Produção Animal - USP/ESALQ, C.P. 9 - CEP: 13418-900 - Piracicaba, SP.
3FAPESP Fellow.
4CAPES Fellow.
*Corresponding author <scdsilva@carpa.ciagri.usp.br>

 

 

ABSTRACT: Several compensatory mechanisms in pastures do not allow optimisation of responses from the processes of herbage production and utilisation. Compensation due to tiller size/density relationships is one of these mechanisms. This experiment evaluated this process for Coastcross bermudagrass and compared the responses to those reported for temperate forages. Treatments were "steady state" sward surface heights of 5, 10, 15, and 20 cm that were maintained from August, 1998, through July, 1999 by sheep grazing. The experimental design was a randomised complete block, replicated four times. Pasture responses were evaluated on four separate dates (15/12/1998, 25/01/1999, 07/04/1999 and 04/07/1999) with respect to: tiller population density, tiller weight, leaf mass and leaf area per tiller and herbage mass (biomass). Tiller volume, leaf area index (LAI), tiller leaf:stem ratio and tiller leaf area:volume ratio (R) were calculated. Simple regression analyses between tiller population density and tiller weight were also performed. Coastcross swards showed a tiller size/density compensation mechanism where high tiller population densities were associated with small tillers and vice-versa; except on the last evaluation. However, regression analysis revealed linear coefficients of -3.83 to -2.05, which are lower than the theoretical expectation of -3/2. The lower R values observed, when compared to those reported for perennial ryegrass, suggest that Coastcross swards optimised their LAI via clonal integration among tillers in contrast with tillers of cool-season grasses that respond more as individuals. However, this hypothesis has yet to be experimentally verified.
Key words: Cynodon, LAI, tiller, morphology

 

COMPENSAÇÃO TAMANHO/DENSIDADE POPULACIONAL DE PERFILHOS EM PASTAGENS DE CAPIM COASTCROSS

RESUMO: Vários mecanismos compensatórios em pastagens não permitem a otimização de respostas dos processos determinantes da produção e da utilização de forragem. O mecanismo de compensação tamanho/densidade é um desses mecanismos. Este experimento avaliou esse processo originalmente descrito para plantas forrageiras de clima temperado. Os tratamentos corresponderam às alturas de pasto de 5, 10, 15 e 20 cm mantidas em steady state por ovinos em lotação contínua de Agosto de 1998 a Julho de 1999. O delineamento experimental utilizado foi o de blocos completos ao acaso, com quatro repetições. As respostas avaliadas foram: densidade populacional de perfilhos, massa por perfilho, massa de folhas e área foliar por perfilho e biomassa total. Cálculos de volume por perfilho, índice de área foliar (IAF), relação folha:haste por perfilho e área foliar:volume do perfilho (R) foram executados. Análises de regressão simples entre densidade populacional de perfilhos e peso por perfilho foram também realizadas. As avaliações foram realizadas em dezembro/98, janeiro, abril e julho/99. Pastos de Coastcross apresentaram um mecanismo de compensação tamanho/densidade onde altas densidades populacionais estiveram associadas com perfilhos pequenos e vice-versa, exceto na última avaliação. Contudo, a análise de regressão revelou inclinações de reta que variaram de -3,83 a -2,05, superiores à expectativa teórica de -3/2. Em dezembro e janeiro os aumentos em biomassa foram resultado de aumentos em massa por perfilho. Os baixos valores de R observados, quando comparados àqueles determinados para azevém perene, sugerem que pastos de Coastcross otimizem seu IAF via integração clonal entre perfilhos, diferentemente de azevém que operaria através de perfilhos individuais. No entanto, esta hipótese necessita ser comprovada experimentalmente.
Palavras-chave: Cynodon, IAF, perfilho, morfologia

 

 

INTRODUCTION

Pastures are characterised by a complex integration of factors that result in very specific and dynamic patterns of responses. In grass swards there are several compensatory mechanisms operating and "buffering" overall responses in terms of herbage production and utilisation. Among these processes, tiller size/population density compensation (SDC) is one of the most intriguing mechanisms and has been studied intensively during recent years (Matthew et al., 1995; Sackville Hamilton et al.,1995; Hernández Garay et al., 1999).

In grass plants the vegetative unit is the tiller (Hodgson, 1990). Pastures are a population of single tillers (Mitchell & Glenday, 1958; Korte, 1986; Colvill & Marshall, 1984) which implies that increases in herbage production can be generated from increases in tiller numbers, tiller weight or a combination between them (Nelson & Zarrough, 1981; Bircham & Hodgson, 1983; Grant et al., 1983; Volenec & Nelson, 1983). However, tillers are subjected to a SDC mechanism which leads to a small population density of large tillers under lenient defoliation or a high population density of small tillers under intense defoliation (Bircham & Hodgson, 1983; Grant et al., 1983; Matthew, 1992; Hernández Garay et al., 1999).

Originally, it was supposed that SDC followed the self-thinning rule proposed by Yoda et al. (1963), widely discussed in the literature (White & Harper, 1970; White; 1980; 1981; 1985; Westoby, 1984), where the relationship between tiller weight and population density (in a log ´ log scale) followed a linear regression line with slope -3/2. However, some authors have questioned its universal use for all species (Weller, 1987; 1989; 1990; 1991; Zeide, 1985, 1987) claiming that not all observations follow the self-thinning dynamics defined by the -3/2 line. In undefoliated grass swards SDC was observed according to a -3/2 line, except in situations of low light intensity (Kays & Harper, 1974; Lonsdale & Watkinson, 1982). Generally, it has been assumed that swards under grazing also follow this rule (Bircham & Hodgson, 1983; Lambert et al., 1986; Davies, 1988). On the other hand, visual analysis of data from Davies (1988) suggested a systematic lack of fit to the -3/2 theoretical line (Sackville Hamilton et al., 1995) and pointed to an inclination steeper than -3/2, around -5/2. Matthew et al., (1995) also observed an inclination steeper than -3/2 in defoliated perennial ryegrass swards (Lolium perenne L.).

Despite all arguments, Sackville Hamilton et al. (1995) demonstrated that -3/2 is a theoretical expectation when LAI and leaf area:plant size remain constant. Considering that sward leaf area varies during regrowth or in response to defoliation intensity (Bircham & Hodgson, 1983; Matthew et al., 1995; Fagundes, 1999), it seems natural that SDC would assume slope values different from -3/2 in grazed swards. Besides LAI, Sackville Hamilton et al. (1995) demonstrated that adjustments in the -3/2 line are related to variations in morphogenetic characteristics of tillers in different sward surface heights. As a consequence, these authors developed an index, R, that relates leaf area per tiller to tiller volume. This index reflects changes in tiller form as the tiller is submitted to different defoliation intensities independently of tiller size, and accounts for the lack of proportionality between variations in leaf and pseudostem/stem length as tillers get taller.

In order to understand the self-thinning rule and its relationship with the SDC mechanism operating in pastures it is necessary to adjust for variations in LAI (function of the rates of leaf tissue growth and removal) and in R (function of morphogenetic variations in tillers as they adjust to different sward heights) (Matthew et al., 1995). These corrections for LAI and R were proposed by Matthew et al. (1995) and designated Ca and Cr, respectively. These two correction factors are a function of variations in tiller population density as swards are kept short or tall. For perennial ryegrass these two factors accounted for almost all the deviation normally observed between the theoretical SDC slope of -3/2 and the calculated value from data sets of experiments where grass swards were kept under predefined defoliation regimes (Matthew et al., 1995; Hernández Garay et al., 1999). Matthew et al. (1995) observed inclinations for the self-thinning lines close to -5/2 in perennial ryegrass swards with the deviation from the -3/2 line being explained when Ca and Cr were considered. The same was true for a data set from Davies (1988), which validated the adjustments for temperate grass species, particularly perennial ryegrass.

A theoretical understanding of the deviations between the observed field values and those of the -3/2 line has important biological implications. Matthew et al. (1995) suggested that the distance between any point and the -3/2 theoretical line when plotting tiller weight against tiller population density could represent a sward productivity index since the -3/2 line defines a situation where LAI is constant (Sackville Hamilton et al., 1995). As a consequence, a longer distance between a given point and the -3/2 line would indicate a larger dry matter production. This hypothesis was confirmed by a series of experiments in micro swards (Hernández Garay et al., 1999) and field conditions (Bahmani et al., 1998).

The objective of the present experiment was to assess if such a SDC mechanism operates in a prostrate tropical grass species and to study the relationships between tiller weight and population density in grazed swards of 'Coastcross' bermudagrass [Cynodon spp. (L.) Pers.].

 

MATERIAL AND METHODS

The experiment was carried out at Unidade Experimental de Plantas Forrageiras (UEPF), Departamento de Produção Animal da E.S.A. "Luiz de Queiroz", Universidade de São Paulo, Piracicaba-SP, Brazil, located at 22o42'30'' south latitude, 47o38'00'' west longitude and 546 m altitude (Ometto, 1989). Four evaluations were performed throughout the experimental period on the following dates: 15/12/98; 25/01/99; 07/04/99 and 04/07/99.

Pastures and experimental period

The experiment was set up on a Eutric Kandiudalf (Terra Roxa Estruturada) with a high soil fertility level (TABLE 1). No phosphorus fertiliser or lime were applied either at pasture establishment or throughout the experimental period. Pastures were first established vegetatively in March 1996, but due to some climatic constraints and poor plant establishment some areas had to be vegetatively replanted during February and March 1997. In 1997 a total of 150 kg N ha-1 was applied as ammonium sulphate. In 1998 pastures received 40 kg N ha-1 as ammonium sulphate in January, July and September, 50 kg N ha-1 on 21 October and 25 kg N ha-1 on 7 December. A standard cut was done in March 1998 at 3 cm from ground level. Sheep were added to experimental units when the target sward surface heights were reached (May). In 1999 N was applied only twice; 23 February (50 kg N ha-1) and 7 March (75 kg N ha-1). Nitrogen applications and timings were planned to generate enough herbage accumulation to maintain at least two grazing sheep per experimental unit throughout the experimental period (15 December, 1998 to 4 July, 1999).

 

 

Climatic conditions

According to the Köppen system the climate type of Piracicaba region is Cwa, a humid mesothermic subtropical with a dry winter where the average temperature of the coldest month is lower than 18°C and that of the warmest month is higher than 22°C (Brasil, 1960). Meteorological figures during the experimental period are presented in TABLE 2.

Experimental design and monitoring of experimental conditions

Treatments of sward surface height (SSH) were assigned to experimental units, each about 400 m2, according to a randomised complete block design with four replications. The bermudagrass cultivar was allowed to grow to the desired surface heights of 5, 10, 15 or 20 cm, after which swards were maintained at that height from August 1998 until July 1999 through continuous stocking by sheep with variable stocking rate (Figure 1). The average SSH was monitored through 20 rising plate meter readings (RPMR) per experimental unit twice a week. A corresponding sward stick height was also recorded. Once a month a calibration equation between RPMR and its correspondent sward stick height was generated, giving the values of sward height (uncompressed SSH) used as reference to monitor the experimental treatments. Grazing sheep were either added or removed from the experimental units as swards were 20% above or below target SSH, respectively, two to three times a week. Plate readings were used preferably because they were fast and allowed for optimisation of time and labour.

 

 

Assessment of the tiller size/population density parameters

All measurements related to individual tiller traits were made in an 8.5 ´ 14.7 cm quadrat (0.0125 m2). Quadrats were placed on sites presenting the target SSH for a given treatment and two samples per replicate were cut to ground level from each experimental unit using scissors and a razor. Despite the frequency and fairly homogeneous state of swards, particularly short ones, there was some degree of variability across paddocks in terms of SSH. As measurements were related to a set of sward state conditions, sampling areas were previously chosen by using a sward stick to place quadrats on sites presenting the target SSH accordingly. The cut material was placed in plastic bags previously wetted and conditioned in a Styrofoam box with ice to reduce plant dehydration and respiration. All samples were taken to the laboratory and stored in a cold room.

Biomass

For biomass evaluation (kg DM m-2) two 0.25 m2 quadrats were used per experimental unit. Quadrats were placed on sites presenting the target SSH for treatments and the herbage mass within them was cut to ground level by electric sheep shears. Samples were conditioned in plastic bags and stored in a cold room. Each sample was washed to remove soil and dung contamination and dried in a forced draught oven at 65°C for 48 hours prior to weighing.

Fresh and dry weight, leaf area and leaf mass per tiller

Twenty of the cut tillers were selected at random from the 8.5 ´ 14.7 cm quadrat samples. These were weighed and the average fresh weight per tiller (TFW) calculated. After weighing, all green leaf lamina were detached from the tiller axis and had their area measured (LI-3100, LICOR). Values were used to calculate the average leaf area per tiller (LAT). Leaf laminas were then placed into small paper bags and dried in a forced draught oven at 65oC for 48 hours. The same procedure was performed for the combined stem and senescent leaf material. After drying, samples were weighed and the average dry weight live lamina (LW) and stem/senescent material (SSM) per tiller was calculated. Total dry weight per tiller (TW) was calculated as the sum of LW and SSM.

Tiller population density (TPD)

TPD was obtained through the following calculation:

where: HM = herbage mass (biomass) and TW = tiller weight.

Leaf area index (LAI)

Sward LAI was determined according to the following calculation:

where:

TPD = tiller population density (tillers m-2) and LAT = leaf area per tiller (m2 tiller-1).

Tiller volume

Average tiller volume was estimated by a technique based on the immersion of tillers in liquids with known apparent densities. Water (1000 kg m-3) and a lubricant oil (902 kg m-3 at 20°C) were used as references. Tillers floated in water but sank in oil, so it was assumed that tiller apparent density (TAD) was around 950 kg m-3. The estimated value proved to be quite robust since variations in actual densities would generate a 5% maximum variability in the final estimates of tiller volume. So, the average volume per tiller (TV) was calculated as:

where: TFW = tiller fresh weight (kg) and TAD = tiller apparent density (950 kg m-3).

Tiller leaf area:volume ratio (R)

The tiller leaf area:volume ratio proposed by Sackville Hamilton et al. (1995) was calculated as:

where:

LAT = leaf area per tiller (m2), where LAT is powered at 3/2 to allow for an adimensional value (Sackvillle Hamilton et al., 1995) and TV = tiller volume (m3).

Regressions log (TPD) x log(TW)

Linear regressions based on Ordinary Least Square (OLS) between TPD and TW were generated using treatment means, which corresponded to four sets of paired data for each evaluation date. Following the procedure described by LaBarbera (1989), cited by Sackville Hamilton et al. (1995), slopes generated by OLS were divided by the correlation between log (TPD) and log (TW) resulting in the Reduced Major Axis (RMA) slopes, which were used for treatment comparisons.

Ca and Cr and the distance between observed points and the theoretical -3/2 line

Estimates of the correction factors for the deviations between the actual regression lines and the -3/2 line for each sample data were made according to Matthew et al. (1995):

and

where: LAI = sward leaf area index; TPD = tiller population density (no/m2) and R = tiller leaf area:volume ratio.

Ca and Cr were calculated as being the slopes for the regressions between sward LAI and TPD and R and TPD, respectively. According to Matthew et al. (1995), the distance between any given point and the -3/2 line placed below the plotted points can be used as a sward productivity index. In this experiment the perpendicular distance between the plotted points for log (TPD) ´ log (TW) and the -3/2 line (constant LAI and R) was calculated.

Statistical analysis

Data were analysed using PROC GLM (General Linear Models) and PROC REG from the statistical package SAS (Statistical Analysis System). Analysis of variance was performed using the Repeated Measures option since all variables were measured sequentially throughout the experimental period (SAS Institute, 1988). All data sets were tested for normality and homogeneity of variances prior to the general analysis, and comparisons between treatment means were performed using LSMEANS.

 

RESULTS AND DISCUSSION

Statistical analysis showed effects of evaluation date and SSH for TW, LW, TV, LAT, biomass and tiller leaf:stem ratio (all at P<0.10). There was a evaluation date effect and a evaluation date ´ SSH interaction for TPD, and a SSH effect for R and LAI (all at P<0.10).

Tiller population density

There was a steady increase in TPD from evaluation date 1 to evaluation date 3 (TABLE 3), when values stabilised. The smaller TPD observed in date 1 was probably a consequence of the dry spell observed in November (TABLE 2). In December, when rainfall returned to normal, TPD increased. Despite no SSH effect, there was a trend for tall swards to present lower TPD than short swards at evaluation dates 1 and 2. These results are in agreement with data generated from temperate forages, where higher TPD were associated with swards kept short (Bircham & Hodgson, 1983; Matthew et al., 1995; Hernández Garay et al., 1999). Conversely, swards maintained at 10 cm during evaluation 3 presented a TPD higher than those kept at 5 cm, indicating that Coastcross swards were not able to compensate the reduced SSH by increasing tiller numbers. Hernández Garay et al. (1999) and Bircham & Hodgson (1983) reported a similar situation for perennial ryegrass where frequent defoliation resulted in lower TPD for their most severe defoliation treatment. This situation fits into a theoretical condition described by Matthew et al. (1995) where a high defoliation intensity can, under certain circumstances, restrict tillering activity in grass plants.

 

 

On date 4, a reverse trend of increasing TPD with increasing swards surface height over the 10 cm to 20 cm height range was observed. This observation is explained the formation, on higher cutting heights, of crowns containing numerous small tillers, and originated from the nodes of decapitated reproductive stems (Carnevalli & Da Silva, 1999).

Tiller dry weight, leaf mass and volume

The highest values of TW were observed on evaluation date 1, with values decreasing as the season progressed (TABLE 4). The same happened for LW and TV (TABLES 5 and 6), a likely consequence of the low rainfall observed in November (TABLE 2), since other growth factors such as light, mineral nutrients and temperature appeared adequate, and plants probably continued to accumulate nutrients via photosynthesis but did not generate growth compatible with that accumulation. Furthermore, there was an increase in TW, LW and TV as SSH increased from 5 to 20 cm (TABLES 4, 5 and 6). These results corroborate those reported for temperate forage plants where taller swards also presented the higher values for leaf mass per tiller, TW (Matthew et al., 1995; Hernández Garay et al., 1999) and TV (Matthew et al., 1995) than shorter ones.

 

 

 

 

Biomass

Biomass yields on dates 1 and 4 were higher than those on dates 2 and 3 (TABLE 7). An increase in biomass was observed with increasing SSH. TPD has often been used as a measure of sward vigour and productivity (Binnie & Chestnut, 1991; Thom & Bryant, 1993). Some studies, however, have demonstrated the importance of the interaction between TPD and TW as determinants of productivity (Langer, 1979; Bircham & Hodgson, 1983). It has been considered that tiller formation is more important when TPD is low (Nelson & Zarrough, 1981; Volenec & Nelson, 1983). This situation was verified on sampling dates 3 and 4 in the present experiment. On date 3 the increase in TW between 5 and 10 cm swards was about 30% while on dates 1 and 2 it was more than 100% (TABLE 4). On those dates, however, herbage biomass increased about 52%, demonstrating that increments in biomass were greatly influenced by TPD, which increased 39% between 5 and 10 cm swards on date 3 (TABLE 3). On date 4, TW increased only 3% from 15 to 20 cm swards (TABLE 4) and biomass showed a corresponding increase of around 53% (TABLE 7), which resulted from the 47% increase in TPD (TABLE 3). On the other hand, factors determining increases in biomass on dates 1 and 2 were related to TW, since a reduction in TPD was observed as SSH increased. Volenec & Nelson (1983) recognised that TW could be more important than TPD in determining sward productivity under certain circumstances.

 

 

Leaf area per tiller and sward leaf area index

The highest values of LAT were observed on dates 1 and 2 (TABLE 8) but there was no time effect for sward LAI (TABLE 9). Matthew at al. (1999) noted that LAI is determined by three components: tiller population density, number of live leaves per tiller and mean area of live leaf lamina. The number of live leaves per tiller is relatively constant for a given grass species or cultivar (Davies, 1977; Yang et al., 1998; Carnevalli & Da Silva, 1999). Leaf lamina area of grasses depends greatly on leaf lamina length, which is a function of defoliation intensity. As a consequence, TPD is the LAI component that allows for a greater flexibility of plants to adjust to different defoliation regimes and is the reason why LAI is optimised in hard-grazed swards through a high TPD of small tillers. Conversely, in lax-grazed swards optimisation of LAI is achieved through a lower TPD of larger tillers (Matthew et al., 1999). Despite the highest values of LAT being observed on dates 1 and 2, LAI did not vary accordingly. This happened because TPD had a major role in determining sward LAI, showing a tendency to increase over time and compensate the decrease in LAT (TABLES 3, 8 and 9).

 

 

 

Tiller leaf:stem and tiller leaf area:volume (R) ratios

Tiller leaf:stem ratio decreased as SSH increased, with the lowest ratios measured on date 3 (TABLE 10). Tiller leaf area:volume ratio (R) varied slightly throughout the experimental period. Tillers of similar shape subjected to differing rates of leaf removal, can be expected to have a higher R with higher sward heights (lower R with lower sward heights) (Matthew et al., 1995; Hernandez Garay et al., 1999). Such an effect was seen on date 2 (TABLE 11). As swards matured, sward structure changed. By date 4 tillers in 10 to 15 cm swards had developed distinct stems (and showed a lower R) while many tillers in 20 cm swards had 'rosetas' of small, leafy tillers, which increased the mean R value for the sward as a whole. The tiller leaf area:volume ratio (R) was originally proposed by Sackville Hamilton et al. (1995) and its calculation uses LAT powered at 3/2 as a means of allowing for an adimensional value. According to Hernández Garay et al. (1999), measurements of tiller leaf:stem ratio are inadequate to estimate parameters related to SDC since leaf and stem are plant components that possess different dimensions that are ignored by the simple calculation based on mass (kg). So, increases in SSH can consistently lead to decreased leaf:stem ratios simply by the fact that in order to endure the weight of leaves the diameter of stems is altered in direct proportion of the force required to support them and not isometrically to the organ weight (McMahon, 1973; McMahon & Kronauer, 1976; Niklas, 1994).

 

 

 

Despite some variation in R values, they were not different statistically with the overall mean value around 15 (TABLE 11). Hernandez Garay et al. (1999) reported R values around 50 for perennial ryegrass and these became higher as SSH increased, indicating that perennial ryegrass grew by developing more leaf area than stem length per tiller. Matthew et al. (1995) discussed that inter-specific variations in R could have some ecological implications. According to those authors, plants presenting high values of R would have a better competitive ability than plants characterised by low R values, an indication of higher individual tiller capacity to pre-emptively capture light in plant communities. On the other hand, low values of R could represent a morphological adaptation towards diminishing the damaging effects of water loss by plants.

One possible reason for the lower values of R observed in this experiment relative to those found in the literature for perennial ryegrass could be the existence of a clonal integration pattern among Cynodon tillers. Matthew et al. (1995) showed that R values in alfalfa (Medicago sativa L.) (plant with a high degree of integration among shoots since they are all generated from a common crown) were higher when calculations were based on the whole plant rather than on single shoots by a factor of n1/2, where n is the number of shoots per crown, indicating that integration is more closely associated with coordinated flushes of development among associated shoots. Coastcross bermudagrass seems to have the same behaviour.

TABLE 12 presents R values assuming an hypothetical clonal integration among four tillers for Coastcross. According to those numbers, R values increased two-fold in all situations and became very close to those values reported by Hernández Garay et al. (1999) for perennial ryegrass. This would suggest that a functional equivalent to having a reduced stem size as a competitive strategy (reduction of sink biomass) is to have clonal integration; and Cynodon tillers use such a strategy. This is in agreement with field observations that a new cluster of tillers is formed along a stolon at regular intervals of three phytomers (leaves) (node with roots and a daughter tiller followed by two successive leaves) (PLATE 1). This structure suggests that one leaf would support root development, a second would support tiller development and a third would support stolon internode elongation.

 

 

 

Another consequence of this strategy is that Coastcross pastures could acquire competitive advantage through clonal integration of tillers. Similar behaviour has not been described in the literature for perennial ryegrass plants, suggesting that those individual plants may operate as discrete units rather than groups. However, further studies under controlled experimental conditions and planned accordingly will be necessary to elucidate the degree and the nature of this integration in order to allow for a better understanding of plant persistence, competitive ability and productivity.

Functional relationship between tiller weight and tiller population density

Simple regression analysis performed on data for dates 1, 2 and 3 revealed the functional relationships presented in TABLE 13. Data from the evaluation for date 4 could not be used due to "rosetas" formation that inflated the TPD values (TABLE 3). The generated slopes (b1) were steeper than the theoretical expectation of -3/2 (Figure 2 and TABLE 13). According to Sackville Hamilton et al. (1995), a -3/2 line would be a theoretical expectation when LAI and R remained constant. Since LAI of Coastcross bermudagrass varied with different SSH (TABLE 9), it would be expected that the slopes observed were different from -3/2. Hernandez Garay et al. (1999) also observed slopes steeper than -3/2 (close to -5/2) for perennial ryegrass swards.

 

 

The correction factors Ca and Cr proved to be effective in accounting for deviations between slope lines in evaluation dates 1 and 2. One of the main factors that could have influenced the discrepancy between the observed slope and the value predicted by Ca and Cr in evaluation date 3 would have been the effect of canopy size on reproductive growth of Coastcross swards, where SSH treatments went into flowering at different times. This could have modified sward structure and affected the key variables used for predicting the slopes: TPD, TV and LAT (TABLES 3, 6 and 8).

Despite these limitations, estimated values for Ca were higher than those for Cr, indicating that in Coastcross pastures the variation in LAI is the main factor determining the tiller size/density compensation, similar to perennial ryegrass swards (Matthew et al., 1999; Hernández Garay et al., 1999). The variation in R is a comparatively minor element of plant growth strategy in the vegetative phase, but R does fall in reproductive phase, allowing the sward to accommodate greater TPD than would otherwise have been the case. This is similar to Lolium perenne (Matthew et al., 1995) but not necessarily true for all grasses.

Practical implications

Matthew et al. (1995) suggested that the distance between any given point defined by its co-ordinates TW and TPD (in a log scale) and the -3/2 theoretical line could have a value as a sward productivity index. As demonstrated by Sackville Hamilton et al. (1995), the -3/2 line defines a situation where LAI is constant. It follows that the greater the distance between the observed points and the -3/2 line the larger the LAI and, consequently, the greater the sward capacity in accumulate herbage dry matter. This hypothesis was confirmed for temperate forage plants in micro swards (Hernández Garay et al., 1999) and in field conditions (Bahmani et al., 1998).

The distance between the observed points and the -3/2 line and the actual sward LAI were correlated (TABLE 14). These coefficients were significant, indicating that the distance measured could, in fact, be used to predict LAI in Coastcross swards, a key sward structure variable, for a proper understanding of herbage accumulation processes in pastures (Lemaire & Agnusdei, 1999). TW and TPD are sward variables that are easier to measure than LAI, justifying further studies in order to allow a better understanding of their relationship with sward LAI and intra-specific competition processes that could generate conditions for using them as predictors of LAI and herbage dry matter production. It is important to mention that the theory of Matthew et al. (1995) assumed all tillers in a population were of similar shape/type with no variation in biomass per unit volume and a new theory may be needed for mixed populations with different types/shapes of tillers mixed together with possible variations in tiller apparent density (kg DM m-3).

 

 

CONCLUSIONS

The tiller size/density compensation mechanism originally described for temperate forage plants also operates in Coastcross pastures. As in temperate grasses, it follows a slope steeper than the theoretical proposition of -3/2.

R values for Coastcross bermudagrass were lower (about 15) than for perennial ryegrass (about 50). A possible reason is that Cynodon tillers operate in groups (clusters) in order to ensure competitive ability and optimise LAI.

The SDC mechanism was dependent on time of the year with Coastcross pastures maintained at 5 cm sward height not being able to compensate for decreased tiller size by increasing tiller numbers during autumn.

The reproductive phase of growth interfered significantly with processes related to intra-specific competition and tiller population dynamics in Coastcross pastures.

 

ACKNOWLEDGMENTS

To FAPESP (Fundação de Amparo à Pesquisa do Estado de São Paulo) for financial assistance and support, to the students of GEPF (Grupo de Estudos de Plantas Forrageiras) for their help and cooperation throughout the experimental period and to Dr. Cory Matthew, Massey University, New Zealand, for his valuable comments and suggestions during the execution of this experiment.

 

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Received January 31, 2000