The present investigation was carried out in the experimental unit of the Instituto Tecnológico de Pinotepa, located at kilometer 26 of the Pinotepa Nacional highway, Oaxaca-Acapulco, south of the town of San José Estancia Grande, Oaxaca, in the period from August to December from 2017 and laboratory analyzes in the same experimental unit from January to June 2018.

It is located at 16˚22' north latitude and 98˚13' west longitude, with a height of 60 masl according to the Köeppen climate classification, it presents an Aw (w) ig climate, it corresponds to a sub-humid warm climate [20], with a rainy season in summer. The pluvial precipitation is in a range of 1000 - 1500 mm annually with a rainy period that includes from June to September with 8 months of drought, with an average temperature of 26˚C - 28˚C.

The sowing was carried out on August 10, 2017, with pure viable seed from three grasses of the Urochloa genus. The sowing method was direct, at a distance between furrow and furrow of 50 cm and between plants of 20 cm. Four 10 × 5 m plots were sowed, being experimental units for each grass. These are in turn in eight areas, in order to evaluate a growth analysis with eight regrowth ages. The soil with a sandy clay texture, pH 4.8 to 5.0, deficient in organic matter. The weed was controlled manually with the help of a hoe, two nitrogen fertilizations were carried out with urea (46-00-00), the first was done on September 28 and the second was on October 17, 2017. On October 12, 2017, a homogenization cut was made at a height of 10 cm in all the experimental plots. Irrigation was carried out every 3 days by the drip method from the date of the cut until completed the investigation.

To determine the changes in the density of stems, at the beginning of the experiment, two PVC rings of 10.4 cm diameter were placed in each experimental unit, which delimited a tiller. All the stems present inside the ring were marked with cable rings of the same color, which were considered as the initial population. Subsequently, each week for eight weeks, the new stems were marked with different colored rings; a different color was used for each generation, and the dead stems were counted and the ring was removed.

Total growth, net growth and foliar senescence were evaluated in a 2 m long transept, five stems of each grass were randomly selected and identified with wire rings of different color. Stems measured: the length of the foliar blade, from the base of the ligule to the apex in green leaves or to the base of the chlorotic tissue in senescent leaves. A linear regression equation was obtained considering the foliar area as the dependent variable and the rib length as the independent variable [21].

The leaf:stem relation data was obtained by cutting two 50 × 50 cm squares weekly in each experimental plot, leaving 10 cm of remaining foliar area; separating into leaf and stem, and it was deposited in a forced air stove at 55˚C until constant weight, recording the weight to estimate the dry matter per hectare, at the different phenologies, dividing the leaf between the stem.

The weight per stem was recorded one day before weekly cutting, 10 stems of each grass were cut at ground level, dried in a forced air stove at 55˚C until constant weight and their weight was recorded. The average weight per stem was obtained by dividing the total weight by the number of stems harvested.

The data were analyzed using a completely randomized block design with arrangement in divided plots and four replications, the procedure used was PROC GLM [22], where the cutting frequency effects were considered as fixed. The multiple comparison of means of the treatments was performed using the Tukey test (α = 0.05).

Figures 1(a)-(c) show the stem density throughout the experimental period in the three grasses of the genus Urochloa. From day 49 to 56, the highest stem density was recorded, independently of the grass (P = 0.05). Signal grass (Figure 1(c)) had the highest stem density with an average of 450 m⁻² stems, while the Insurgent grass meadow (Figure 1(a)) registered the lowest stems density throughout the investigation, with an average 320 m⁻² stems; furthermore, in this treatment, the stem density tended to increase slower over time; with a multiple average of 376 m⁻² stems.

On average, all the grasses presented lower stem density at the beginning of the growth curve (day 7), and it can be attributed to the beginning of the growth curve since at the beginning of the regrowth the tillers tend to have a lower population of stems and the largest foliar area and, therefore, the higher the weight with time to establish the meadow [23]. Another factor that affected this behavior of stems was the inter-specific competition for nutrients, water, light and space [24], since the plants do not regrowth in a meadow as isolated individuals, but as a usually dense population, where the vegetation that It surrounds them exerts a very strong influence on the inherent characteristics of each species, through competition [17].

Other authors, [25] in the dry tropics in the population density of stem, obtained similar results to this study when evaluating regrowth patterns of Elephant grass (Pennisetum purpureum) subjected to two pre-grazing heights (90 and 120 cm), where they observed 293 m⁻² stems in the initial regrowth state, followed by a significant increase and the highest values in the intermediate state (420 m⁻² stems) and a decrease in the final state (331 m⁻² stems); on the other hand, when evaluating the Llanero grass (Andropogon gayanus Kunt) they reported an average of 350 stems m⁻² in a growth curve, results similar to those of this test [26]. On the other hand, [27] when evaluating the Cuba 22 grass in the tropics of Mexico, it obtained a smaller population than that of this study with an average of 76 stems m⁻²; being highly variable and depends on various factors such as type of grass, climate and management given on the plot.

Figures 2(a)-(c) show the leaf elongation, net growth and senescence per stem of three Urochloa grasses (Insurgent, Piata and Signal) by varying the phenological state. The leaf elongation (accumulated growth) the grass that obtained the highest contribution was Piata followed by Insurgent and at the end Signal with an average of 140, 134 and 115 cm stem⁻¹ respectively, and multiple average of 130 cm stems⁻¹ (P ≤ 0.05). The Insurgent and Signal grasses showed a rapid leaf elongation from day 21 of regrowth with 123 and 104 cm stem⁻¹, while in Piata the accelerated leaf elongation was on day 14 with 113 cm stem⁻¹ where it remained active its growth until day 56 (P > 0.05). Similar behavior was obtained the net growth reporting the highest net growth by Piata grass with 134 cm stem⁻¹ and the lowest Signal with 108 cm stem⁻¹ (P > 0.05). The Insurgent and Signal grass the net growth was increasing as the phenology stage passed until reaching the maximum point on day 49 and then descending on day 56; however, in Piata grass, it increased without decreasing (P > 0.05; Figure 2(b)). Regarding the growth of senescence in the Insurgent grass, it was reported from day 21 with 3.7 cm stem⁻¹ increasing considerably until reaching on day 56 the maximum senescence with 21.8 cm stem⁻¹ obtaining the highest amount of senescence per stem (P > 0.05). With regard to Signal and Piata grass, senescence began from day 28 of regrowth, remaining constant until day 56.

Several authors [21] [28] mention that at the end of the forage accumulation curve senescence losses increase and, therefore, the net forage accumulation decreases as in this investigation. In Cobra grass (Urochloa hybrid) and Cuba 22 (Pennisetum purpureum x Pennisetum glaucum) the maximum leaf growth occurs in the seventh; then growth rates decrease due to a progressive increase in stems and senescent material [16] [27]. The highest growth and trend of these Urochloa grasses is related to a promotion of division and lengthening cell, known effects of cytokinins on cotyledons and leaves of mustard (Brassica nigra) cucurbits (Cucurbita pepo) and sunflower (Helianthus annuus) [29]. After defoliation, the speed with which a forage recovers depends on the reserve carbohydrates in roots, remaining leaf area and the number of vegetative buds started, which increases the photosynthetic capacity of the leaves; and higher elongation and net foliar growth [13].

Figures 2(a)-(c) show the leaf:stem relation of the Insurgent, Piata and Signal grasses by varying phenological states. The leaf:stem relation is a measure of the quality of the meadow since if it is higher than 1 it means that the leaf exceeds the quantity of stem in the meadow. Independently of the grass, the leaf:stem relation decreased as the evaluation period passed (P = 0.05). The highest leaf:stem relation was reported in Piata, Signal and Insurgent grass, 7 days after regrowth with values of 8, 6 and 5, respectively (P = 0.05). Staying Insurgent and Signal until day 42 of regrowth a leaf:stem relation of 2.4 and lower Piata on that same day 1.8 (P > 0.05); decreasing until day 56 with an average leaf:stem relation of 1.4. In addition, tillering growth habit and semi-erect growth of the Urochloa grasses, the high leaf:stem relations and the minimal growth of senescence can be explained, because it is concentrated in the lower strata of the meadow that in this case is left 10 cm of remaining foliar area. On the other hand, this behavior of decreasing the leaf:stem relation as the evaluation time increases is closely related to the decrease in net growth and increase in senescence as shown in Figure 2.

Similar results were obtained by other researchers [27] obtaining a higher leaf:stem relation in early phenologies and decreasing as the time and senescence of the plant increased, obtaining on day 30 a leaf:stem ratio of 2.4 and on day 110 of regrowth 0.8. In Mombaza grass (Panicum maximum Jacq.), when evaluating different cutting frequencies in the rainy and dry season, reported a decrease in leaf:stem ratio in dry (80%) compared to the rain; in addition, when the frequency increases, the leaf:stem relation decreases on average on day 21, 8.4 decreasing on day 49 with 3.8 of leaf:stem relation, trend and results similar to those of this study [30]. Other researchers [15] in mulatto I (Brahiaria hybrid) now Urochloa report similar results to those of this investigation, they mention that the high values of leaf:stem relation were associated with the management given in the meadow, mainly leaving remaining foliar area, which prevented a large amount of stem from being harvested, which is located close to the soil surface.

Figures 2(a)-(c) show the weight per stem (g) of three grasses of the Urochloa genus in growth curves. Independently of the grasses, the weight per stem decreases as the evaluation time passes. The highest weight per stem was obtained in the Piata grass at 56 days of regrowth with 1.8 g, followed by Signal on day 49 with 1.7 and finally Piata on the same day with 1.6 g (P > 0.05). However, the lowest weight per stem was obtained by Signal grass with 0.1 g on day 7 after evaluation (P > 0.05).

The weight per stem is closely related to the forage yield since as the weight per stem increases, the weight of a tiller and therefore a meadow increases [23]. In this regard, the age of the plant is a factor that determines an increase in weight per stem and senescent material and decreases leaf formation [15]. On the other hand, when evaluating Cuba 22 grass in the dry tropics, they reported the same trend and higher weights per stem than those of this investigation; however, they evaluated a species with higher height, yield, therefore, the weight per stem was higher [27].